JP6069993B2 - Lighting - Google Patents

Description

  The present invention relates to an improvement of an illuminating lamp having a solid state light emitting device, and more particularly to an illuminating lamp capable of saving energy with a simple and inexpensive configuration when connected to a rapid start type ballast or an inverter type electronic ballast. .

  Conventionally, instead of a fluorescent lamp having a filament electrode, an illumination lamp using, for example, a light emitting diode (LED) as a solid light emitting element with low power consumption has been proposed (see, for example, Patent Document 1).

  According to the technique disclosed in Patent Document 1 or the like, not only a lighting device for a glow starter type fluorescent lamp and a lighting device for a rapid start type fluorescent lamp can be attached with an illuminating lamp having a solid light emitting element, but also fluorescent light. An illuminating lamp having a solid light-emitting element can be attached to a luminaire equipped with an inverter-type electronic ballast for the lamp.

  By the way, the illuminating lamp disclosed in Patent Document 1 is provided with a resistor in front of the full-wave rectifier, and a current limit is applied between the full-wave rectifier and the solid-state light emitting element by a constant current circuit or the like. A circuit is provided, and the heating current from the ballast is circulated to the ballast via a resistor, so that the solid-state light emitting element is turned on without power failure, but the configuration is generally complicated. In addition, there is a case where the fluorescent lamp does not match the impedance and does not light.

  Therefore, in order to recirculate the power supplied from the ballast to the ballast as a reactive current, it is conceivable to provide a condenser used for the recirculation of the reactive current in the lighting lamp. When the condenser used for reflux is provided in the illuminating lamp, when the illuminating lamp having the solid light emitting element is mounted on the two sockets of the luminaire for the fluorescent lamp, the situation and power saving that cannot be assumed when the fluorescent lamp is mounted There may be a situation where the effect cannot be obtained.

  The present invention provides an illuminating lamp capable of stably saving power even when an illuminating lamp using a solid-state light emitting element is connected to a ballast such as a rapid start type ballast or an inverter type electronic ballast. There is to do.

The illuminating lamp of the present invention includes a base having a pair of terminal pins inserted into one of two sockets of a fluorescent lamp lighting fixture and connected to a ballast, and two sockets of the fluorescent lighting fixture And the other base having a pair of terminal pins connected to the ballast, and an alternating current that is electrically connected to the pair of terminal pins of the one base and supplied from the one base A first bridge-type full-wave rectifier that rectifies the alternating current supplied from the other base connected to the pair of terminal pins of the other base. A smoothing capacitor connected between a rectifying unit and two DC power supply lines configured by connecting the first bridge-type full-wave rectifying unit and the second bridge-type full-wave rectifying unit; Solid state light emission connected in parallel to a smoothing capacitor A lamp with a child, and
The reactive current capacitor that recirculates the alternating current output from the ballast as a reactive current can be regarded as being electrically symmetrical with respect to the two sockets of the lighting fixture for the fluorescent lamp. A pair of terminal pins and a pair of terminal pins of the other base are connected.

  According to the illuminating lamp of the present invention, the pair of terminal pins of the one base and the base of the other base are arranged so that the reactive current capacitor can be regarded as being electrically symmetrical with respect to the two sockets of the fluorescent lamp luminaire. Since it is connected to the pair of terminal pins, the power consumption can be reduced regardless of the manner of connection of the illumination lamps with a simple structure and low cost.

FIG. 1 is a cross-sectional view showing an outline of a luminaire having a ballast for an existing fluorescent lamp to which an illuminating lamp having a solid light emitting device according to an embodiment of the present invention can be attached. FIG. 2 is a front view schematically showing the appearance of an illuminating lamp that can be attached to the luminaire shown in FIG. FIG. 3 is a connection diagram of an illuminating lamp using the solid state light emitting device according to Example 1 of the invention. FIG. 4 is an explanatory view showing a modification of the connection diagram of the illuminating lamp using the solid state light emitting device according to the first embodiment of the present invention. FIG. 5 is a connection diagram of an illuminating lamp using a solid state light emitting device according to Example 2 of the present invention.

Hereinafter, an illumination lamp according to an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is an external view showing an outline of a lighting fixture provided with a ballast such as a rapid start ballast or an inverter type electronic ballast for an existing fluorescent lamp to which an illuminating lamp having a solid light emitting element according to the present invention can be attached. It is.

Example 1
In FIG. 1, reference numeral 1 denotes a reflector umbrella to which a straight tube type illumination lamp described later is mounted. The reflector 1 is provided with a pair of sockets 2, 2 ′ at both ends in the extending direction. The reflector 1 is provided with a ballast 3 such as an existing rapid start ballast or an inverter type electronic ballast for a fluorescent lamp capable of supplying power from a commercial AC power source E.

  An existing straight tube fluorescent lamp can be attached to this lighting fixture, but here, instead of this existing straight tube fluorescent lamp, a straight tube illumination lamp 4 shown in FIG. 2 is attached. It is done. In this illuminating lamp 4, both ends of the straight tube 5 are sealed with a pair of caps 6, 6 '. One of the caps 6 is provided with a pair of terminal pins 7a and 7a 'which are inserted into one of the two sockets 2 and 2' of the fluorescent lamp lighting fixture and connected to the ballast 3. Yes.

The other cap 6 ′ is provided with a pair of terminal pins 7b and 7b ′ which are inserted into the other socket 2 ′ of the two sockets 2 and 2 ′ of the lighting fixture for fluorescent lamps and connected to the ballast 3. ing.
As shown in FIG. 3, a commercial AC power source E is connected to the ballast 3. The frequency of the commercial AC power source E is, for example, 50 Hz / 60 Hz.

The output side of the ballast 3 is connected to a pair of sockets 2, 2 '. One socket 2 has a pair of electrode terminals 2a and 2a '. The other socket 2 ′ has a pair of electrode terminals 2b and 2b ′.
A pair of terminal pins 7a and 7a 'are inserted and connected to the pair of electrode terminals 2a and 2a'. A pair of terminal pins 7b and 7b 'are inserted and connected to the pair of electrode terminals 2b and 2b'.

  As shown in FIG. 3, a plurality of solid state light emitting elements (for example, light emitting diodes (LEDs)) 8 are provided inside the straight pipe 5. The plurality of solid state light emitting devices 8 are connected in series to form a series light emitter 9 formed of a serial connection body. Here, the series light emitters 9 are provided in parallel in at least three rows.

A pair of terminal pins 7a and 7a 'of one base 6 is electrically connected to a first bridge-type full-wave rectifier 12 that rectifies an alternating current supplied from the base 6 into a direct current. Yes.
A second bridge-type full-wave rectifier 12 'that rectifies an alternating current supplied from the other base 6' into a direct current is electrically connected to the pair of terminal pins 7b, 7b 'of the other base 6'. Has been.

The first bridge-type full-wave rectification unit 12 and the second bridge-type full-wave rectification unit 12 ′ are composed of known rectification diodes D1 to D4.
Between two DC power supply lines (+ line and − line) 10 and 10 ′ configured by connecting the first bridge type full wave rectification unit 12 and the second bridge type full wave rectification unit 12 ′. Is connected to a smoothing capacitor 13.

The smoothing capacitor 13 has a role of removing AC components included in DC currents output from the output sides of the first bridge-type full-wave rectifier 12 and the second bridge-type full-wave rectifier 12 '. Both ends of each series light emitter 9 are connected in parallel to the smoothing capacitor 13.

One terminal pin 7a of a pair of terminal pins 7a, 7a 'of one base 6 and one terminal pin 7b of a pair of terminal pins 7b, 7b' of the other base 6 'are electrically connected by a line L1. ing.
The other terminal pin 7a 'of the pair of terminal pins 7a, 7a' of one base 6 and the other terminal pin 7b 'of the pair of terminal pins 7b, 7b' of the other base 6 'are electrically connected by a line L2. It is connected.
A first reactive current capacitor C1 is interposed in the middle of the line L1, and a second reactive current capacitor C2 is interposed in the middle of the line L2.

  The capacities of the reactive current capacitors C1 and C2 are determined by the number of arrangements of the solid state light emitting devices 8, but when the ballast 3 is a rapid ballast, it is 0.1 microfarad or more from the viewpoint of power saving. In addition, it is preferably 10 microfarads or less, in particular, 1 microfarad or 2 microfarads. For example, a 0.47 microfarad capacitor may be used. When the ballast 3 is an inverter type ballast, it is desirable that the ballast 3 is not less than 1,000 picofarads and not more than 10,000 picofarads.

  According to the first embodiment, when the power switch SW shown in FIG. 3 is turned on, the ballast 3 is turned on, and a part of the commercial AC current is stabilized as schematically shown by arrows Z1 and Z2 in FIG. Since it is recirculated as a reactive current to the vessel 3, power saving can be achieved.

  In addition, according to the first embodiment, the reactive current capacitors C1 and C2 for circulating the alternating current output from the ballast 3 as the reactive current are connected to the pair of sockets 2 and 2 ′ of the lighting fixture for the fluorescent lamp. And is connected to the pair of terminal pins 7b, 7a 'of the one base 6 and the pair of terminal pins 7b, 7b' of the other base 6 'so that it can be regarded as being electrically symmetrical. Thus, power consumption can be reduced regardless of the connection method.

The reason will be described below.
Usually, the distance between the electrode terminals 2a and 2a 'of the socket 2 connected to the ballast 3 (the electrode terminals 2b and 2b' of the socket 2 ') is about 5 volts. The potential difference between 2a and the electrode terminal 2b of the socket 2 '(potential difference between the electrode terminal 2a' of the socket 2 and the electrode terminal 2b 'of the socket 2') is about 100 volts.

Therefore, the potential difference between the electrode terminal 2a of the socket 2 and the electrode terminal 2b of the socket 2 'is between the electrode terminals 2a, 2a' of the socket 2 connected to the ballast 3 (electrode terminals 2b, 2b 'of the socket 2'). Compared to (the potential difference between the electrode terminal 2a 'of the socket 2 and the electrode terminal 2b' of the socket 2 '), it is regarded as the same potential.

  In the case of a straight tube fluorescent lamp, a filament is connected to each of the pair of terminal pins of one of the pair of bases and the pair of terminal pins of the other base, so that they are electrically symmetrical. Even if the insertion into the pair of sockets 2 and 2 'is reversed left and right, it is not necessary to pay attention to the way of connection.

On the other hand, when the reactive current capacitor is provided in the illuminating lamp having the solid state light emitting element so as to be electrically left-right asymmetrical, the insertion into the pair of sockets 2, 2 ′ is reversed left or right, or When the connection is reversed, the connection method is different, and it is necessary to pay attention to the connection method. When the connection is reversed, the power saving effect cannot be obtained.
Therefore, in the present invention, the reactive current capacitor is provided in the illuminating lamp so as to be electrically symmetrical in the same manner as when a fluorescent lamp is connected.

(Modification)
As schematically shown in FIG. 4, one terminal pin 7a of a pair of terminal pins 7a, 7a 'of one base 6 and the other terminal pin 7b of a pair of terminal pins 7b, 7b' of the other base 6 '. The first reactive current capacitor C1 is interposed in the middle of the line L3 that electrically connects to the other terminal pin 7a, the other terminal pin 7a 'of the pair of terminal pins 7a, 7a' and the other base 6 The second reactive current capacitor C2 may be interposed in the middle of the line L4 that electrically connects one terminal pin 7b of the pair of terminal pins 7b and 7b '.
Also in the case of this modification, it can be made into an electrically symmetrical shape as in the case of a fluorescent lamp.

(Example 2)
In the first embodiment, two reactive current capacitors C1 and C2 are provided to provide an electrically symmetrical shape. However, as shown in FIG. 5, a pair of terminal pins 7a, 7a 'is connected by a line L5 so that it can be regarded as a short-circuited state, and a pair of terminal pins 7b, 7b' of the other base 6 'is connected by a line L6 so that it can be regarded as a short-circuited state. The pin 7a, 7a 'and the pair of terminal pins 7b, 7b' of the other base 6 'may be connected by a line L7 and connected to the line L7 via a reactive current capacitor C1.

  In the case of the second embodiment, since the pair of terminal pins 7a and 7a 'of the base 6 are connected by the line L5, the terminal pin of the base 6 can be regarded as one electrical terminal. Since the pair of terminal pins 7b and 7b 'are also connected by the line L6, the terminal pin of the base 6' can be regarded as substantially one electrically. Therefore, the terminal pin of the base 6 and the base 6 ' The number of reactive current capacitors C1 interposed between the terminal pins can be reduced.

  Further, the degree of freedom of connection of the reactive current capacitor C1 increases. A resistor of 10Ω or less may be interposed in the middle of the lines L5 and L6.

2, 2 ′, socket 3, ballast 4, illumination lamp 6, one base 6 ′, the other base 7 a, 7 a ′, 7 b, 7 b ′, a pair of terminal pins 8, solid light emitting element 9, series light emitter 10 DESCRIPTION OF SYMBOLS 10 '... DC power supply line 12 ... 1st bridge type full wave rectifier 12' ... 2nd bridge type full wave rectifier 13 ... Smoothing capacitor

JP 2008-277188 A

Claims (6)

One base having a pair of terminal pins inserted into one of the two sockets of the lighting fixture for the fluorescent lamp and connected to the ballast;
The other base having a pair of terminal pins inserted into the other of the two sockets of the lighting fixture for the fluorescent lamp and connected to the ballast;
A first bridge-type full-wave rectifier that is electrically connected to a pair of terminal pins of the one base and rectifies an alternating current supplied from the one base;
A second bridge-type full-wave rectifier that is electrically connected to a pair of terminal pins of the other base and rectifies an alternating current supplied from the other base;
A smoothing capacitor connected between two DC power supply lines configured by connecting the first bridge-type full-wave rectification unit and the second bridge-type full-wave rectification unit;
A solid-state light emitting device connected in parallel to the smoothing capacitor,
The reactive current capacitor that recirculates the alternating current output from the ballast as a reactive current can be regarded as being electrically symmetrical with respect to the two sockets of the lighting fixture for the fluorescent lamp. An illuminating lamp characterized by being connected to a pair of terminal pins and a pair of terminal pins of the other base.   A first reactive current capacitor is interposed in the middle of a line that electrically connects one of the pair of terminal pins of the one base and one of the pair of terminal pins of the other base. 2. The second reactive current capacitor is interposed in the middle of a line that electrically connects the other of the pair of terminal pins and the other of the pair of terminal pins of the other base. The illuminating lamp described.   A first reactive current capacitor is interposed in the middle of a line that electrically connects one of the pair of terminal pins of the one base and the other of the pair of terminal pins of the other base. 2. The second reactive current capacitor is interposed in the middle of a line that electrically connects the other of the pair of terminal pins and one of the pair of terminal pins of the other base. The illuminating lamp described. The pair of terminal pins of the one base is connected so as to be regarded as a short circuit state, and the pair of terminal pins of the other base is connected so as to be regarded as a short circuit state, and the pair of terminal pins of the one base and the The illuminating lamp according to claim 1, wherein the pair of terminal pins of the other base is connected via a reactive current capacitor.   5. The method according to claim 1, wherein, when the ballast is a rapid start type ballast, a capacitance of the reactive current capacitor is not less than 0.1 microfarad and not more than 10 microfarad. 6. The illumination lamp according to item 1.   5. The method according to claim 1, wherein when the ballast is an inverter-type electronic ballast, a capacitance of the reactive current capacitor is not less than 1,000 picofarads and not more than 10,000 picofarads. The illuminating lamp described.