JPH0728774Y2 - Power supply circuit for multi-scan display - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Industrial Field of the Invention The present invention relates to a power supply circuit for a multi-scan display, which can suitably support different numbers of scanning lines.

2. Description of the Related Art A multi-scan display is suitable for different scanning line numbers when displaying signals of different color television systems such as NTSC system and PAL system or PAL system and SECAM system. In addition, even in the same system, the number of scanning lines is doubled to be suitable for non-interlaced scanning.

As a power supply circuit for such a multi-scan display, a two-system power supply having a fixed voltage output and a voltage that changes according to the deflection frequency is required, but conventionally, these voltages were formed by separate power supply circuits. .

Problems to be Solved by the Invention Therefore, there has been a problem that the conventional power supply circuit has a large number of configurations and a high cost.

The present invention has been made in view of these points.
It is an object of the present invention to provide a power supply circuit that simplifies the system by combining the power supplies of the systems.

Means for Solving the Problems In order to achieve the above object, a power supply circuit for a multi-scan display according to the present invention includes a primary coil of a first transformer, a primary coil of a second transformer, and a switching element between a DC voltage source and a ground. Are connected in series, the first rectifier circuit is connected to the secondary coil of the first transformer, and the second rectifier circuit is connected to the output terminal of the secondary coil of the second transformer via a saturable reactor. A third detection output coil of the flyback transformer in the horizontal output circuit is connected to the output of the second rectifier circuit and the output of the detection coil on the secondary side of the horizontal output circuit is composed of a diode and a smoothing capacitor. Connected to a rectifier circuit, the third
The output of the rectifier circuit is connected to the control terminal of the first transistor, a Zener diode is connected between the other control terminal of the first transistor and a reference potential point, and the output of the first transistor is connected to the control terminal of the second transistor. And the output of the second transistor is connected to the connection between the saturable reactor and the second rectifier circuit.

The fixed voltage generating first transformer and the variable second transformer are driven by the same switching element. Second
The pulse generated on the secondary side of the transformer is rectified by the rectifier circuit and becomes the power supply voltage of the horizontal output circuit. In the flyback transformer and the horizontal deflection circuit of the horizontal output circuit supplied with this voltage, the output of the secondary side high voltage coil of the flyback transformer decreases when the frequency of the horizontal deflection increases. However, since the pulse width varying means acts to narrow the width of the pulse from the second transformer based on the signal obtained by the secondary side detection coil, the power supply voltage supplied to the horizontal output circuit rises and the fly voltage is increased. The drop in the high voltage output of the back transformer is corrected.

Embodiment Hereinafter, the present invention will be described according to an embodiment shown in the drawings. In the figure, (1) is a plug to be plugged into an outlet, (2) is a power-on switch, (3) is a full-wave rectifier circuit, and (4) is its smoothing capacitor.

This capacitor (4) equivalently serves as a DC voltage source.
(5) is the first transformer, (6) is the second transformer,
The primary coils (7) and (8) are connected in series, and one end of the primary coil (7) is connected to the capacitor (4). Further, one end of the primary coil (8) is connected to the collector of the switching transistor (9). A drive signal is applied to the base of the switching transistor (9), and the drive signal is controlled to be constant by the detection output from the detection winding (10) wound around the first transformer (5). Has been done.

The primary side of the first and second transformers (5) and (6) is configured as an RCC (ringing choke converter) system together with the switching transistor (9), but this RCC system is well known and will not be described in detail here. To

The secondary side of the first transformer (5) has a plurality of secondary coils (11
a) to (11e) are wound, and rectifier diodes (12a) to (12e) and smoothing capacitors (13a) to (13) are wound around them.
e) is connected. The secondary coils (11a) to (1
The pulse generated in 1e) is rectified and smoothed, and the secondary coil (11
Fixed DC voltage (+ B ₁ ) according to the number of turns from a) to (11e)
To (+ B ₅ ). These DC voltage (+ B ₁ )
To (+ B ₅ ) are supplied to predetermined circuits. On the other hand, the pulse (15) generated in the secondary coil (14) of the second transformer (6) passes through the saturable reactor (16) and is composed of diodes (17) and (18), a capacitor (20) and a choke coil (19). It is supplied to the rectifying and smoothing circuit (21), converted into a DC voltage here, and applied to the horizontal output circuit (22) as a power supply voltage. The horizontal output circuit (22) includes an output transistor (23), a damper diode (24), a resonance capacitor (25), a horizontal deflection coil (26), an S-shaped correction capacitor (27), and a flyback transformer (28). It is configured. (29) represents the drive signal of the horizontal output transistor (23). Flyback transformer (28)
In addition to the high-voltage coil (30) and the high-voltage rectifier diode (31) provided on the secondary side, a detection coil (32) is provided. (33) is a diode that rectifies the output pulse of the detection coil, and (34) is a smoothing capacitor.
The output voltage is applied to the base of the transistor (37) from the connection midpoint (C) of the resistors (35) and (36).

The emitter of this transistor (37) is connected to ground via a constant voltage diode (38), and the collector is connected to the base of a PNP transistor (39). A voltage is applied to the emitter of the PNP transistor (39) from the point (b) through the resistor (40), and the collector is the diode (41).
Is connected to point (a) via.

Next, the operation will be described. Switching transistor (9)
The pulses generated in the secondary coils (11a) to (11e) of the first transformer (5) by the switching operation of are rectified by the rectifier diodes (12a) to (12e), respectively, and fixed DC voltage (+ B ₁ ) to (+ B ₁ ) to ( + B ₅ ).

On the other hand, the pulse (15) generated in the secondary coil (14) of the second transformer (6) is supplied to the rectifier circuit (21) through the saturable reactor (16), is rectified therein, and is then output to the horizontal output circuit (22). To the power supply voltage.

If the horizontal deflection frequency is set higher in the horizontal output circuit (22), the peak value of the high-voltage pulse generated in the high-voltage coil (30) will be low, and the high-voltage pulse will be rectified by the high-voltage rectifier diode (31). The high voltage output obtained as a result also decreases. This high-voltage output is applied to the anode electrode of a cathode ray tube (not shown), and its decrease means that the screen size changes as is well known. Now, when the horizontal deflection frequency is set to the higher side as described above, the pulse generated in the detection coil (32) also becomes smaller. as a result,
The voltage generated at point (c) decreases, the conductivity of the transistor 37 decreases, and the bias of the PNP transistor (39) also decreases, resulting in the PNP transistor (39) → diode (41) →
(A) Point → Saturable reactor (16) → Secondary transformer secondary coil (14) → The current flowing through the path of ground is reduced. When the bias current decreases, the saturable reactor (16) increases the width of the pulse (15) supplied from the secondary coil (14) to the rectifier circuit (21). By this (b)
The potential at the point (power supply voltage of the horizontal output circuit) rises, the high-voltage pulse generated in the high-voltage coil (30) of the flyback transformer (28) becomes large, and the drop in the high-voltage output is corrected.

Thus, the potential at point (b) (the power supply voltage of the horizontal output circuit)
And the high voltage output of the flyback transformer (28) is kept constant so that the size of the screen in the cathode ray tube can be kept constant. The potential at point (c) is stable at the voltage value obtained by adding V _BE of the transistor (37) to the zener voltage of the zener diode (38), but as described above, the horizontal deflection frequency increases and When the potential starts to drop,
The conductivity of the transistor 37 decreases, and the above-mentioned loop acts to restore the potential at point (c) to its original value (return to the stable point).

Incidentally, when the horizontal deflection frequency is lowered, the potential at point (c) rises due to the operation reverse to that described above, so that it acts to return it to the stable point. This means lowering the potential at point (b), thereby holding the high voltage output constant.

As described above, according to the present invention, the high voltage output of the flyback transformer is kept constant regardless of the change of the horizontal deflection frequency, and such a configuration is used for generating a fixed voltage by one switching element. Second driven with one transformer
Since it is applied to the output voltage of the transformer, there is an effect that the power supply circuit configuration as a whole is simplified.

[Brief description of drawings]

FIG. 1 is a circuit diagram of a power supply circuit for a multi-scan display embodying the present invention. (4) ... smoothing capacitor (DC current), (5) ... first transformer, (6) ... second transformer, (7) ... primary coil of first transformer, (8) ... second transformer Primary coil, (11a) to (11e) …… Secondary coil of first transformer, (14) …… Secondary coil of second transformer, (16) …… Saturable reactor (pulse width variable means), ( 21) rectifier circuit, (22) horizontal output circuit, (28) flyback transformer, (32) detection coil.

Claims (1)

[Scope of utility model registration request] 1. A primary coil of a first transformer, a primary coil of a second transformer, and a switching element are connected in series between a DC voltage source and ground, and a first rectifier circuit is connected to a secondary coil of the first transformer. And connecting a second rectifier circuit to the output terminal of the secondary coil of the second transformer via a saturable reactor, and connecting the output of the second rectifier circuit to the power input section of the horizontal output circuit. The output of the detection coil on the secondary side of the flyback transformer in the horizontal output circuit is connected to a third rectifying circuit composed of a diode and a smoothing capacitor,
The output of the rectifier circuit is connected to the control terminal of the first transistor, a Zener diode is connected between the other control terminal of the first transistor and a reference potential point, and the output of the first transistor is connected to the control terminal of the second transistor. And a power supply circuit for a multi-scan display, wherein the output of the second transistor is connected to a connecting portion between the saturable reactor and the second rectifier circuit.