JP2559624Y2 - Horizontal deflection output circuit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Industrial application field The present invention relates to a horizontal deflection circuit provided in a CRT display device, and more specifically, a horizontal deflection output capable of simultaneously obtaining a horizontal deflection output and a high voltage output. It is related to the circuit.

(B) Conventional technology A horizontal deflection output circuit capable of simultaneously obtaining a horizontal deflection output and a high voltage output by one circuit is called a one-series horizontal deflection output circuit. The conventional circuit is shown in FIG. I do.

(Q ₁ ) is a horizontal output transistor whose base is connected to a horizontal drive circuit (not shown) and operates in response to a signal from the horizontal drive circuit.
(B ₁ ) is a DC voltage, (L ₁ ) is a deflection coil that scans an electron beam emitted from an electron gun (not shown), (L ₂ ) is a linearity coil that corrects the horizontal difference of the horizontal linearity of the screen, (D ₁ ) Is a damper diode, (C ₁ ) is a resonance capacitor, (C ₂ ) is an S-shaped correction capacitor, (T ₁ ) is a flyback transformer, (T ₂ ) is a pin cushion transformer,
(R ₄ ) is the regulation improvement resistor, (R ₂ ) is the ABL (automatic current limit) detection resistor, and (HV) is the high voltage output of the flyback transformer (T ₁ ).

In such a configuration, the horizontal output transistor (Q ₁ )
Is non-conductive, a pulse of about 1 KV _op is generated at the collector of the transistor (Q ₁ ). The pulse voltage is boosted and rectified by a flyback transformer (T ₁ ), and a high voltage output (HV) is output as an anode voltage of a cathode-ray tube (CRT) (not shown).

Pressure value issue high voltage output (HV) to (c) devised to solve is as shown in the high-pressure rectification waveform diagram of FIG. 3, varies with the CRT beam current value (I _B). Pressure value is decreased when the beam current value (I _B) is increased,
Since the deflection efficiency is improved, both the horizontal amplitude and the vertical amplitude of the image are increased.

Therefore, in the conventional horizontal deflection output circuit, a regulation improvement resistor (R ₄ ) is inserted between the DC power supply (B ₁ ) and the flyback transformer (T ₁ ) in order to suppress the fluctuation of the horizontal amplitude. ing.

According to the regulation improvement resistor (R ₄ ), when the beam current value (I _B ) increases, the current flowing through the regulation improvement resistor (R ₄ ) increases, and the voltage applied to the flyback transformer (T ₁ ) decreases. I do. This reduces the deflection current and further reduces the high voltage value, but consequently,
Fluctuations in the horizontal amplitude of the image are suppressed.

However, this method has a disadvantage in that the fluctuation of the high voltage value is further increased, so that the fluctuation of the luminance and the vertical amplitude of the image is increased as compared with the case where the regulation improvement resistor (R ₄ ) is not used.

There is also a method in which the high-voltage output and the horizontal output are separately configured to stabilize the high-voltage and the image amplitude as a two-series horizontal deflection output circuit. There were many problems in practical use.

The horizontal deflection output circuit of the present invention has been made in view of such circumstances, and it is desirable to provide a horizontal deflection output circuit having a high voltage and excellent image amplitude stability while being a series of horizontal deflection output circuits. Aim.

(D) Means for Solving the Problems The horizontal deflection output circuit of the present invention comprises a horizontal output transistor, a horizontal deflection coil and a flyback transformer connected in parallel to the transistor, and outputs a horizontal deflection output and a high voltage output. In the horizontal deflection output circuit that can be obtained, the secondary high voltage winding and the primary low voltage winding of the flyback transformer are connected, and the high voltage output is fed back from the secondary high voltage winding to provide the secondary deflection voltage. A constant voltage circuit for controlling the output to the primary low-voltage winding so that the high-voltage output voltage from the secondary high-voltage winding is constant, and a saturable reactor connected in series to the horizontal deflection coil; A control coil is connected to a secondary high voltage winding of the flyback transformer, and a saturable reactor whose inductance is controlled by a change in beam current flowing through the secondary high voltage winding.

(E) Operation The high voltage output is kept constant by the constant voltage circuit, so that the vertical amplitude is kept constant even if the beam current changes. On the other hand, when the beam current flowing through the high-voltage winding changes, the constant voltage circuit operates to increase or decrease the horizontal amplitude, but the saturable reactor operates to decrease or increase the horizontal amplitude. , The horizontal amplitude becomes constant.

(F) Embodiment FIG. 2 is a schematic configuration diagram for explaining the principle of the present invention. In this figure, the same parts as those in FIG. A saturable reactor (T ₃ ) is connected between the pin cushion transformer (T ₂ ) and the S-shaped correction capacitor (C ₂ ), and the high voltage winding (1) and the resistor (R ₁ ) of the flyback transformer (T ₁ ) are connected. ), The control winding (2) of the saturable reactor (T ₃ ) is connected to GND.

In operation, the inductance of the saturable reactor (T ₃ ) decreases as the DC current (I ₁ ) increases.

 Such an operation can be represented by the following equation.

Ignoring the DC resistance value of the saturable reactor (T ₃ ),
There is the following relationship:

When _{R 2 (I 1 + I B} ) + R 1 I 1 = B 1 ... (1.1) deforms the above _{equation, I 1 = (B 1 -R} 2 I B) / (R 1 + R 2) ... (1.2) , and the As the beam current value (I _B ) increases, the DC current (I ₁ ) decreases.

That is, when the beam current value (I _B ) increases, the inductance of the saturable reactor (T ₃ ) increases, thereby suppressing an increase in horizontal amplitude.

Next, FIG. 1 shows an example of a circuit configuration when the horizontal deflection output circuit of the present invention is employed in a multi-scan monitor, and will be described below.

In the figure, the constant voltage circuit (B ₁ ′) is a high voltage output (HV)
There are feedback pressure value of the high voltage output (HV) is different variety of the horizontal synchronization signal frequency (or horizontal oscillation frequency, simply referred to as a horizontal frequency less) and the beam current value (I _B) and independent of Operate to be constant.

Due to the operation of the constant voltage circuit (B ₁ ′), the vertical amplitude becomes constant even when the beam current value (I _B ) changes, but the horizontal amplitude increases as the beam current value (I _B ) increases.

One end of a control winding (2) of the saturable reactor (T ₃ ) is connected to an emitter of a horizontal amplitude adjusting transistor (Q ₂ ). The transistor (Q ₂ ) is for adjusting the horizontal amplitude, and can change the horizontal amplitude by changing the base voltage (V _c ) applied to the base.

(B ₂ ) is a DC power supply.

Since the beam current value (I _B ) is supplied from the DC power supply (B ₂ ) via the ABL detection resistor (R ₂ ), the current (I ₂ ) increases as the beam current value (I _B ) increases.

Here, if the base voltage (V _c ) is constant, the current (I ₃ ) is also constant, and the currents (I ₁ ), (I ₂ ), and (I ₃ ) have the following relationship.

I ₁ + I ₂ = I ₃ ≒ V _c / R ₁ (2.1) That is, if the current (I ₂ ) increases, the current (I ₁ ) decreases.

Therefore, when the beam current value (I _B ) increases, the current (I ₂ ) also increases, so that the current (I ₁ ) decreases and the inductance of the saturable reactor (T ₃ ) increases.

Thus, when the beam current value (I _B ) increases, the constant voltage circuit (B ₁ ′) operates to increase the horizontal amplitude,
Since the saturable reactor (T ₃ ) operates to reduce the horizontal amplitude, the horizontal amplitude becomes constant as a result.

(G) Effects of the Invention As described above, the horizontal deflection output circuit of the present invention can provide a horizontal deflection output circuit having excellent high voltage and excellent image amplitude stability, while being a series of horizontal deflection output circuits. .

[Brief description of the drawings]

1 and 2 are diagrams relating to the horizontal deflection output circuit of the present invention, FIG. 1 is a circuit configuration diagram, and FIG. 2 is a schematic configuration diagram for explaining the principle. FIG. 3 is a high voltage rectification waveform diagram,
FIG. 4 is a circuit diagram showing a conventional horizontal deflection output circuit. 1 high-voltage winding of flyback transformer, 2 control winding of saturable reactor, B ₁ DC voltage, B ₁ ′ constant voltage circuit,
C ₁ … Resonant capacitor, C ₂ … S-shaped correction capacitor, D ₁ … Damper diode, L ₁ … Deflection coil, L ₂ … Linearity coil, Q ₁ … Horizontal output transistor, Q ₂ … Horizontal amplitude adjustment transistor, Q ₃ … Current amplifying transistor, R ₁ … Resistor, R ₂ … ABL detection resistor, R ₄ … Regulation improvement resistor, T ₁ … Flyback transformer, T ₃ … Pin cushion transformer, T ₃ … Saturable reactor.

Claims (1)

(57) [Scope of request for utility model registration] 1. A horizontal deflection output circuit comprising a horizontal output transistor, a horizontal deflection coil and a flyback transformer connected in parallel to the transistor, and capable of obtaining a horizontal deflection output and a high voltage output. The high voltage output from the secondary high voltage winding is fed back by connecting the high voltage output from the secondary high voltage winding to the secondary high voltage winding and the primary low voltage winding of the back transformer. And a saturable reactor connected in series to the horizontal deflection coil, wherein the control winding is the same as that of the flyback transformer.
A horizontal deflection output circuit, comprising: a saturable reactor connected to a secondary high-voltage winding and having an inductance controlled by a change in beam current flowing through the secondary high-voltage winding.