JP5111415B2 - Trance - Google Patents

Description

  The present invention relates to a transformer for a discharge lamp lighting device, for example.

  An apparatus for lighting a fluorescent lamp is required to save energy and extend its life by reducing CO2 and improving efficiency.

  Patent Document 1 describes the structure of a transformer used in a circuit having a fluorescent lamp discharge lamp as a load. For example, a structure of a preheating winding for preheating the electrode of the discharge lamp is described as a structure of a transformer when the discharge lamp is turned on by a push-pull circuit.

JP 9-35885 A

  An object of the present invention is, for example, to secure a window area for winding a primary winding and to ensure insulation performance between the primary winding and the secondary winding.

  The transformer of the present invention includes a primary winding section on which a primary winding is wound and a section on one side of both sides sandwiching the primary winding section, and the first secondary winding is wound around the section. A first secondary winding section and a section on one side of the sections on both sides of the primary winding section that are not the first secondary winding section, and the second secondary winding is A bobbin having a wound second secondary winding section; a first separator partitioning the primary winding section and the first secondary winding section; the primary winding section; And a second separator that partitions the second secondary winding section.

  According to the present invention, for example, a window area for winding the primary winding can be secured, and insulation performance between the primary winding and the secondary winding can be secured.

1 is a circuit diagram of a discharge lamp lighting device 100 according to Embodiment 1. FIG. 1 is an external view of a ballast choke 200 according to Embodiment 1. FIG. FIG. 3 is a layout diagram of the coil of the ballast choke 200 and the connection terminal 209 according to the first embodiment. FIG. 3 shows a printed circuit board 300 according to Embodiment 1. The arrangement | positioning figure of the coil of the ballast choke 200 and the connecting terminal 209 in Embodiment 2 (Example 1). The circuit diagram of the discharge lamp lighting device 100 in Embodiment 2 (Example 2). The arrangement | positioning figure of the coil of the ballast choke 200 and the connecting terminal 209 in Embodiment 2 (Example 2).

Embodiment 1 FIG.
A transformer for a discharge lamp lighting device having a primary winding connected to the discharge lamp and a plurality of secondary windings will be described.

FIG. 1 is a circuit diagram of a discharge lamp lighting device 100 according to the first embodiment.
The discharge lamp lighting device 100 according to Embodiment 1 will be described below with reference to FIG.

  The discharge lamp lighting device 100 includes a rectifier circuit 110, an active filter circuit 120, an inverter circuit 130, an inverter control circuit 140, a ballast choke 200, and a lamp load circuit 160.

The rectifier circuit 110 rectifies the AC voltage (current) from the commercial power supply 101.
The active filter circuit 120 smoothes the voltage rectified by the rectifier circuit 110.
The inverter circuit 130 outputs the voltage smoothed by the active filter circuit 120 at a high frequency.
The inverter control circuit 140 controls the switching element 131 of the inverter circuit 130.
The ballast choke 200 and the lamp load circuit 160 turn on the lamp (discharge lamp) with the voltage output from the inverter circuit 130.

  The discharge lamp lighting device 100 lights two hot cathode discharge lamps (hereinafter referred to as discharge lamps) (102, 103) connected in series to the ballast choke 200.

  Details of the ballast choke 200 and the lamp load circuit 160 will be described below.

  The ballast choke 200 includes a P coil 210, an S1 coil 211, an S2 coil 212, and an S3 coil 213.

The P coil 210 is a “primary winding”. The primary winding limits the current flowing through the discharge lamp.
The S1 coil 211, the S2 coil 212, and the S3 coil 213 are “secondary windings”. The secondary winding is stored in the preheating capacitor of the lamp load circuit 160 and preheats the electrode of the discharge lamp.

  The lamp load circuit 160 includes a DC cut capacitor 161, a starting capacitor 162, and preheating capacitors (163 to 165) for preheating the electrodes (filaments) of the respective discharge lamps.

  The components of the ballast choke 200 and the lamp load circuit 160 are “inverter circuit 130 → P coil 210 → S1 coil 211 → preheating capacitor a163 → discharge lamp a102 → S2 coil 212 → preheating capacitor b164 → discharge lamp b103 → preheating capacitor c165 → S3. Coil 213 → DC cut capacitor 161 → inverter circuit 130 ”. The starting capacitor 162 is connected in parallel to the S1 coil 211 to the S3 coil 213.

The P coil 210 has one end (P _a ) connected to the power supply side (inverter circuit 130) and the other end (P _b ) connected to the S1 coil 211.
The S1 coil 211 has one end (S1 _a ) connected to the P coil 210 and the other end (S1 _b ) connected to the electrode (A) of the discharge lamp a102 via the preheating capacitor a163 and via the preheating capacitor a163. Then, the electrode (A) of the discharge lamp a102 is preheated.
The S2 coil 212 has one end (S2 _a ) connected to the electrode (B) of the discharge lamp a102 and the other end (S2 _b ) connected to the electrode (C) of the discharge lamp b103 via the preheating capacitor b164. The electrode (B) of the discharge lamp a102 is preheated and the electrode (C) of the discharge lamp b103 is preheated via the preheating capacitor b164.
One end (S3 _a ) of the S3 coil 213 is connected to the electrode (D) of the discharge lamp b103 via the preheating capacitor c165 and the other end (S3 _b ) is connected to the inverter circuit 130 via the DC cut capacitor 161. Then, the electrode (D) of the discharge lamp b103 is preheated.

The preheating capacitor a163 is connected to the electrode (A) on the opposite side (power supply side) to the discharge lamp b103 among the electrodes on both ends of the discharge lamp a102, and preheats the electrode (A) of the discharge lamp a102.
The preheating capacitor b164 is connected to the electrode (B) on the discharge lamp b103 side among the electrodes on both ends of the discharge lamp a102 and is connected to the electrode (C) on the discharge lamp a102 side among the electrodes on both ends of the discharge lamp b103. The electrode (B) of the discharge lamp a102 and the electrode (C) of the discharge lamp b103 are preheated.
The preheating capacitor c165 is connected to the electrode (D) on the opposite side of the discharge lamp a102 among the electrodes on both ends of the discharge lamp b103, and preheats the electrode (D) of the discharge lamp b103.

One end portion (P _b ) of the P coil 210 and one end portion (S 1 _a ) of the S1 coil 211 have a common reference potential.
The electrode (A) of the discharge lamp a102 is on the high pressure side, and the electrode (D) of the discharge lamp b103 is on the low pressure side.

  In FIG. 1, reference numerals (1), (3), (5), (6), (7), (9), and (10) shown at both ends of each coil are connection terminals of a ballast choke 200 described later. Is shown.

FIG. 2 is an external view of the ballast choke 200 in the first embodiment.
The appearance of the ballast choke 200 in the first embodiment will be described below with reference to FIG.

The ballast choke 200 includes a bobbin 201 around which each coil (shaded portion) is wound.
As shown in the top view, the bobbin 201 includes two E-shaped cores (iron cores) (205, 206). The gapless core 206 has the same length of the E-shaped upper protrusion, the central protrusion (dotted line portion), and the lower protrusion. In the core 205 with gap, the length of the E-shaped central protrusion (dotted line portion) is shorter than the upper and lower protrusions of the E-type. The gap-free core 206 and the core 205 with gap are in contact with each other at the upper and lower protrusions of the E-type, and have a gap between the E-shaped central protrusions.
A core tape 207 is affixed to the E-shaped back portion of the core 205 with gap and the E-shaped back portion of the core 206 without gap (see the right side view, for example).

Each coil is wound around an E-shaped central protrusion of the gapless core 206 and an E-shaped central protrusion of the gap-attached core 205. Hereinafter, the E-shaped central protrusion of the gapless core 206 around which each coil is wound and the E-shaped central protrusion of the core 205 with gap are referred to as “core”.
The core has separators (202, 203) one by one near both ends (E-shaped vertical part), and is divided into three sections (291, 293, 292) in the length direction by two separators. Yes.

Hereinafter, the separator on the side of the core 205 with gap is referred to as “separator a202”, and the separator on the side of the core 206 without gap is referred to as “separator b203”.
In addition, a wide section (between the separator a202 and the separator b203) in the middle portion among the three sections is “a wound section a291”, and a narrow section (the separator a202 and the gapted core) on the gaped core 205 side among the three sections. (Between the E-shaped vertical portion of 205) and the narrow section on the gapless core 206 side (between the separator b203 and the E-shaped vertical portion of the gapless core 206) among the three sections. It is referred to as “winding section c293”.

A P coil 210 is wound around the winding section a291, and an S1 coil 211 is wound around the outer circumference of the ballast choke 200 near the separator b203. An insulating tape 208B is sandwiched between the P coil 210 and the S1 coil 211. Moreover, the exterior tape 208A is affixed to the winding section a291.
An S2 coil 212 is wound around the winding section b292, and an S3 coil 213 is wound around the winding section c293.

Each separator insulates the P coil 210 and the S2 coil 212 and the P coil 210 and the S3 coil 213, thereby extending the life of the ballast choke 200.
Further, by providing the winding section b292 of the S2 coil 212 and the winding section c293 of the S3 coil 213, it is not necessary to wind the S2 coil 212 and the S3 coil 213 around the outer periphery of the P coil 210, and the P coil 210 is multiplexed. Can be rolled up.

  The bobbin 201 includes a plurality of connection terminals 209 (for example, notations (5), (7), (3), (9), and (1)) on each of an end on the winding section b292 side and an end on the winding section c293 side. .

FIG. 3 is a layout diagram of the coil of the ballast choke 200 and the connection terminal 209 according to the first embodiment.
In FIG. 3, the separator a202 is arranged on the right side and the separator b203 is arranged on the left side, the core 205 with gap and the non-gap core 206 are removed, a cross section of the core part is shown, and each coil part is indicated by “x” mark. .
The connection relationship between each coil and each connection terminal 209 will be described below with reference to FIG.

  The bobbin 201 has five compartments in which the connection terminals 209 are arranged in a row at each of an end portion on the separator a202 side and an end portion on the separator b203 side. The section on the separator a202 side is indicated as “(5)”, “(4)”, “(3)”, “(2)”, and “(1)” from the front. In addition, the section on the separator b203 side is described as “(6)”, “(7)”, “(8)”, “(9)”, and “(10)” from the front.

In the bobbin 201, the connection terminals 209 are disposed in the sections (5), (3), and (1) on the separator a202 side, and the connection terminals 209 are disposed on the sections (6), (7), (9), and (10) on the separator b203 side. Has been.
Hereinafter, the connection terminal 209 arranged in the section (x) is referred to as “connection terminal (x)”.

The P coil 210 is wound around the winding section a291 and is connected to the connection terminal (1) at one end and to the connection terminal (7) at the other end.
The S1 coil 211 is wound around the outer periphery of the P coil 210, connected to the connection terminal (7) at one end, and connected to the connection terminal (6) at the other end.
The S2 coil 212 is wound around the winding section b292 and connected to the connection terminal (5) at one end and to the connection terminal (3) at the other end.
The S3 coil 213 is wound around the winding section c293, connected to the connection terminal (9) at one end and connected to the connection terminal (10) at the other end.

  By connecting the S2 coil 212 to the connection terminal (5) (3) on the winding section b292 side and connecting the S3 coil 213 to the connection terminal (9) (10) on the winding section c293 side, each coil is connected to another coil. It becomes easy to connect to the connection terminal 209 without touching.

The ballast choke 200 is attached to a printed board described later, and each connection terminal 209 of the ballast choke 200 is electrically connected to each circuit of the discharge lamp lighting device 100 attached to the printed board.
The connection terminal (1) is connected to the inverter circuit 130, the connection terminal (6) is connected to the electrode (A) of the discharge lamp a102 via the preheating capacitor a163, and the connection terminal (5) is the electrode (B of the discharge lamp a102). ), The connection terminal (3) is connected to the electrode (C) of the discharge lamp b103 via the preheating capacitor b164, and the connection terminal (9) is connected to the electrode (D) of the discharge lamp b103 via the preheating capacitor c165. The connection terminal (10) is connected to the DC cut capacitor 161.

  Thereby, each coil of the ballast choke 200 constitutes the circuit shown in FIG.

FIG. 4 is a diagram showing the printed circuit board 300 according to the first embodiment.
The printed circuit board 300 according to the first embodiment will be described below with reference to FIG.

The printed circuit board 300 has a rectangular shape (for example, an aspect ratio of 1: 6 or more), and includes a rectifier circuit unit 310, an active filter circuit unit 320, an inverter control circuit unit 340, an inverter circuit unit 330, a ballast choke unit 350, and a lamp load circuit unit. 360 and the discharge lamp connection part 370 are arranged side by side in order.
For example, in the ballast choke 200, the connection terminals 209 are arranged side by side on the long side of the printed circuit board 300 and attached to the ballast choke portion 350. The connection terminals (1), (3), and (5) of the ballast choke 200 are arranged in parallel with one long side of the printed circuit board 300, and the connection terminals (6), (7), (9), and (10) of the ballast choke 200 are printed circuit boards. Lined up in parallel with the other 300 long side.

  By disposing the ballast choke 200 on the printed circuit board 300 as described above, the conductor pattern of the printed circuit board 300 is not complicated, and it is easy to ensure a wide interval between the conductor patterns.

In the first embodiment, for example, the following discharge lamp lighting transformer (ballast choke 200) has been described.
The discharge lamp lighting transformer is a lamp choke provided in the inverter type hot cathode discharge lamp lighting device.
The bobbin of the discharge lamp lighting transformer has a primary winding (P coil 210) for limiting the lamp current and a plurality of secondary windings (Sx coils) for preheating the electrodes of the hot cathode discharge lamp (lamp). . Further, the bobbin includes respective winding sections of a primary winding and a secondary winding, and a terminal for connection with a printed circuit board at an end.
The discharge lamp lighting transformer has a secondary winding (S2 coil 212, S3 coil 213) arranged in each winding section at the end of the bobbin, and each secondary winding wound around the winding section at the end is Connect to the connection terminal at the nearby end.

The discharge lamp lighting device connects two hot cathode discharge lamps in series, preheats the electrodes, and lights the two discharge lamps.
The discharge lamp lighting transformer has ends of the first electrode preheating winding (S2 coil 212) between the discharge lamps and the second electrode preheating winding (S3 coil 213) having the most potential difference from the primary winding. The third electrode preheating winding (S1 coil 211) connected to the primary winding and arranged in the two winding sections is arranged on the outer periphery of the primary winding.

  The connection terminal (FIGS. 3 (3) and (5)) of the first electrode preheating winding (S2 coil 212) is opposite to the connection terminal (FIG. 3 (7)) of the primary winding to the discharge lamp. The connection terminals (FIGS. 3 (9) and (10)) of the second electrode preheating winding (S3 coil 213) are arranged on the side opposite to the connection terminal of the first electrode preheating winding.

The discharge lamp lighting transformer is disposed on a rectangular printed board having an aspect ratio of, for example, 1: 6 or more so that the terminal portion is parallel to the long side.
The inverter type hot cathode discharge lamp lighting device converts circuit components around the lamp (lamp load circuit section 360), a discharge lamp lighting transformer, a direct-current voltage into a high-frequency voltage, which are arranged on the side close to the end of the printed circuit board The switching elements of the inverter unit (inverter circuit 130) are arranged in order.

The ballast choke according to Embodiment 1 has the following effects, for example.
(1) A winding section (winding section b292, winding section c293) insulated from a primary winding (P coil 210) by a separator is provided, and a secondary winding (S2 coil 212, S3 coil 213) is provided in each winding section. Since it is wound, the reliability of insulation between the windings can be ensured even when the starting voltage is high.
(2) Secondary windings (S2 coil 212, S3 coil 213) other than the secondary winding (S1 coil 211) having the same potential as the primary winding are arranged in a winding section different from the primary winding. Therefore, insulation performance can be ensured without reducing the window area in which the primary winding can be wound.
(3) Since the terminals (connection terminals 209) of the respective windings provided at both ends of the bobbin are provided at the end of the bobbin immediately adjacent to the respective windings, there is no contact with other windings when each winding is guided to the terminal. Securing insulation performance is certain.

When a ballast choke is arranged on a printed circuit board to constitute a discharge lamp lighting device, the direction arrangement of the terminals of the ballast choke becomes important.
By making the ballast choke terminals parallel to the long side direction of the printed circuit board, the insulation distance between the patterns on the printed circuit board can be secured to a predetermined value or more. Furthermore, pattern arrangement on the lamp side circuit components (components attached to the lamp load circuit section 360) and pattern arrangement on the inverter circuit of the primary winding of the ballast choke are facilitated.

The ballast choke 200 may be used other than the discharge lamp lighting device.
Further, in the present embodiment, the case of using a center gap type core in which the ballast choke 200 is combined with a gap and without a gap has been described, but a core having two gaps may be used, Moreover, you may use the core which is not a center gap system.

Embodiment 2. FIG.
Another embodiment of the ballast choke 200 having three winding sections will be described.
Hereinafter, items different from the first embodiment will be mainly described. Matters whose description is omitted are the same as those in the first embodiment.

<Example 1>
An embodiment in which the section around which the P coil 210 is wound is divided into two will be described.

FIG. 5 is a layout diagram of the coil of the ballast choke 200 and the connection terminal 209 according to the second embodiment (Example 1). FIG. 5 corresponds to FIG. 3 of the first embodiment.
The ballast choke 200 in the second embodiment (Example 1) will be described below with reference to FIG.

The ballast choke 200 includes a separator c204 between the separator a202 and the separator b203.
Hereinafter, the section between the separator a202 and the separator c204 is referred to as “winding section a ₁ 294”, and the section between the separator c204 and the separator b203 is referred to as “winding section a ₂ 295”.
The primary winding is wound around the winding section a ₁ 294 as the P1 coil 214 and is wound around the winding section a ₂ 295 as the P2 coil 215. The S1 coil 211 is wound around the outer periphery of the P2 coil 215.

<Example 2>
An embodiment in which one discharge lamp is used will be described.

FIG. 6 is a circuit diagram of discharge lamp lighting device 100 according to the second embodiment (Example 2). FIG. 6 corresponds to FIG. 1 of the first embodiment.
FIG. 7 is a layout diagram of the coils of the ballast choke 200 and the connection terminals 209 according to the second embodiment (Example 2). FIG. 7 corresponds to FIG. 3 of the first embodiment.
A discharge lamp lighting device 100 according to the second embodiment (Example 2) will be described below with reference to FIGS. 6 and 7.

As shown in FIG. 6, one discharge lamp (discharge lamp a102) is connected to the discharge lamp lighting device 100, and two secondary windings are wound around the ballast choke 200 (S1 coil 211, S3 coil 213). ).
As shown in FIG. 7, the P coil 210 is wound around the winding section a291, and is connected to the connection terminal (1) at one end and connected to the connection terminal (7) at the other end.
The S1 coil 211 is wound around the winding section c293, and is connected to the connection terminal (7) at one end and to the connection terminal (6) at the other end.
The S3 coil 213 is wound around the winding section b292, and is connected to the connection terminal (5) at one end and to the connection terminal (3) at the other end.
The connection terminal (1) is connected to the inverter circuit 130, the connection terminal (6) is connected to the electrode (A) of the discharge lamp a102 via the preheating capacitor a163, and the connection terminal (5) is released via the preheating capacitor c165. It is connected to the electrode (B) of the electric lamp a102, and the connection terminal (3) is connected to the DC cut capacitor 161.

  The ballast choke 200 described in the second embodiment has the same effect as the first embodiment by having three winding sections.

DESCRIPTION OF SYMBOLS 100 Discharge lamp lighting device, 101 Commercial power supply, 102 Discharge lamp a, 103 Discharge lamp b, 110 Rectifier circuit, 120 Active filter circuit, 130 Inverter circuit, 131 Switching element, 140 Inverter control circuit, 160 Lamp load circuit, 161 DC cut Capacitor, 162 starting capacitor, 163 preheating capacitor a, 164 preheating capacitor b, 165 preheating capacitor c, 200 ballast choke, 201 bobbin, 202 separator a, 203 separator b, 204 separator c, 205 core with gap, 206 core without gap, 207 Core tape, 208A Exterior tape, 208B Insulating tape, 209 Connection terminal, 210 P coil, 211 S1 coil, 212 S2 coil, 213 S3 coil, 214 P1 coil, 215 P Coil, 291 turns sections a, 292 winding section b, 293 winding section c, 294 winding section _a 1, 295-turn section _a 2, 300 a printed circuit board, 310 rectifier circuit, 320 an active filter circuit, 330 an inverter circuit section, 340 Inverter control circuit section, 350 ballast choke section, 360 lamp load circuit section, 370 discharge lamp connection section.

Claims (4)

1 and winding section third secondary winding on the outer periphery of the primary winding is wound Rutotomoni the primary winding is wound, one of the sides of sections across the primary winding section Of the first secondary winding section on which the first secondary winding is wound and the sections on both sides sandwiching the primary winding section are not the first secondary winding section. A bobbin having a second secondary winding section on one side and wound with a second secondary winding;
A first separator that partitions the primary winding section and the first secondary winding section;
A second separator separating the primary winding section and the second secondary winding section ;
One end of the first secondary winding is connected to the second electrode on the second discharge lamp side among the electrodes on both ends of the first discharge lamp connected in series with the second discharge lamp. Connected,
The other end of the first secondary winding is connected to a third electrode on the first discharge lamp side among the electrodes on both ends of the second discharge lamp,
One end of the second secondary winding is connected to a fourth electrode on the opposite side of the first discharge lamp among the electrodes on both ends of the second discharge lamp,
One end of the third secondary winding is connected to the first electrode on the opposite side of the second discharge lamp among the electrodes on both ends of the first discharge lamp,
The transformer , wherein the other end of the third secondary winding is connected to one end of the primary winding . The bobbin further includes a first terminal portion on the first secondary winding section side and a second terminal portion on the second secondary winding section side, and the first 2 connect following winding to the first terminal portion, claim 1 Symbol mounting of the transformer and the second secondary winding, characterized in that connected to the second terminal portion. The first terminal portion has a plurality of terminals arranged in a row and the second terminal portion has a plurality of terminals arranged in a row, and the plurality of terminals of the first terminal portion and the first terminals 3. The transformer according to claim 2, wherein a plurality of terminals of the second terminal portion are arranged on a long side of a rectangular printed board and connected to the printed board. 4. The transformer according to claim 3 , wherein the transformer is disposed between an inverter circuit portion provided on the printed board and a discharge lamp load circuit portion provided on the printed board and connected to the printed board.

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