JPH085513Y2 - Fluorescent display tube drive circuit - Google Patents

Description

[Detailed Description of the Invention] (a) Field of Industrial Application The present invention has two or more fluorescent display tubes that are driven by applying an alternating voltage to a filament, and has a voltage to be applied to the filament. The present invention relates to a commonly used fluorescent display tube drive circuit. In particular, it relates to improvement of Japanese Utility Model Application No. 62-150326.

(B) Conventional technology As for the filament drive circuit for fluorescent display tubes,
As disclosed in Japanese Unexamined Patent Publication No. 6018 (97 (7) B), a Zener diode is connected between the midpoint of the filament heating power source and the bias reference potential point.

When using a plurality of fluorescent display tubes, if the cutoff voltages of the respective fluorescent display tubes are different, the filament windings of the transformer are required for the number of fluorescent display tubes.

Therefore, the applicant of the present application has proposed in Japanese Patent Application No. 62-107289 a filament drive circuit that shares the voltage of the AC component applied to the filament.

By the way, the brightness of the fluorescent display tube varies depending on the variation in performance.

When only one fluorescent display tube is attached to the device, there is no comparison of the brightness in the surroundings, so this variation is not very noticeable.

However, if you attach two fluorescent display tubes to the device,
Due to the above variation, the difference in brightness of the fluorescent display tubes differs depending on the device, and this difference in brightness (or the ratio of the brightness of the two fluorescent display tubes) is a concern.

Therefore, the applicant of the present invention has applied for a circuit including a bias voltage adjusting means (luminance difference adjusting circuit) for variably adjusting the bias voltage of the filament of at least one fluorescent display tube.
Proposed in No. 62-150326.

An example of such a filament drive circuit is shown in FIG.

This example shows a filament drive circuit of a fluorescent display tube of a video tape recorder (VTR).

Reference numeral (10) is a first fluorescent display tube, which is a fluorescent display tube for a timer for displaying time, tape count value and the like. (12)
Is a second fluorescent display tube, which is a fluorescent display tube for an audio level meter.

(S ₁ ) (S ₂ ) is an anode (segment), (G ₁ )
(G ₂ ) is a grid, and (F ₁ ) (F ₂ ) is a filament. A segment selection circuit (not shown) is connected to (S ₁ ) and (S ₂ ), and a grid drive circuit (not shown) for grid scan is connected to (G ₁ ).
A grid drive circuit (14) is connected to (G ₂ ).

(T) is a transformer, which converts the voltage value of the input AC signal of several 10 KHz. From this transformer (T), an AC signal to be supplied to filaments (F ₁ ) (F ₂ ) is output. The filament (F ₁ ) is directly applied, and the filament (F ₂ ) is applied via the capacitors (C ₁ ) (C ₂ ).

(16) is a first voltage dividing circuit composed of resistors (R ₁ ) and (R ₂ ). Bias voltage setting means (18) described later is connected to the middle point of the first voltage dividing circuit (16).

The second voltage dividing circuit (20) is composed of resistors (R ₅ ) (R ₆ ),
Bias voltage adjusting means (22) described later is connected to the midpoint.

The bias voltage setting means (18) comprises a resistor (R ₃ ) and a zener diode (D ₁ ), and the zener diode (D ₁ )
The Zener potential set in step 1 is output to the midpoint of the first voltage dividing circuit (16) as a bias voltage.

The bias voltage adjusting means (22) is a resistor (R ₇ ) (R ₈ )
(R ₉ ) (R ₁₀ ), variable resistance (VR), transistor (Q ₂ ), Zener diode (D ₃ ) (D ₄ ),
By adjusting the value of the variable resistor (VR), the value of the bias voltage supplied to the midpoint of the second voltage dividing circuit (20) is adjusted. With this adjustment, the fluorescent display tube (1
2) The brightness is adjusted.

(C) Problems to be solved by the invention By the way, when this circuit was actually driven, uneven brightness occurred in the fluorescent display tube (10) for timer.
This uneven brightness is the effect of the grid scan for driving the level display fluorescent display tube (12).

Fig. 3 shows the filament voltage waveform of the fluorescent display tube for a timer (10) when the fluorescent display tube for a level meter (12) is not driven. The ripple shown in FIG. 3 is produced when the fluorescent display tube (10) for the timer is driven, but since this corresponds to the drive of each grid of the display tube (10), unevenness does not occur.

FIG. 4 shows a voltage waveform of the filament (F ₁ ) of the fluorescent display tube (10) for timer when the fluorescent display tube (12) for level meter is driven.

When the grid voltage of the level indicator fluorescent display tube (12) is positive, the filament current on the level meter side increases. Ideally, this fluctuation is cut by the capacitors (C ₁ ) and (C ₂ ) and does not affect the fluorescent display tube (10) for timer. However, this capacitor (C ₁ ) (C ₂ ) is for passing an AC signal of several tens of KHz, and the grid scan signal of about 100 Hz inevitably affects it. Therefore, the resistance (R ₁ ) (R ₂ ) is greater than the resistance of the Zener diode (D ₁ ).
The current flowing through the capacitors (C ₁ ) (C ₂ ) increases. As a result, the current value of the Zener diode (D ₁ ) increases, and the voltage difference between the two electrodes of the Zener diode (D ₁ ) also fluctuates and increases. Therefore, the cathode potential of (D ₁ ) fluctuates, and the (cutoff) bias becomes unstable.

That is, the fluorescent display tube for timer (1) synchronized with the application of the grid voltage to the fluorescent display tube for level meter (12).
The voltage fluctuation of 0) (ripple R in FIG. 4a) is naturally not synchronized with the application of the grid voltage of the fluorescent display tube for timer (10), and therefore uneven brightness occurs.

(D) Means for Solving the Problems The present invention is directed to the filament (F) of the first fluorescent display tube (10).
The output of the transformer (T) is applied to ₁ ), and the transformer (T) is applied to the filament (F ₂ ) of the second fluorescent display tube (12).
Is applied via capacitors (C ₁ ) (C ₂ ) to the first and second fluorescent display tubes (10) and (12), which are respectively connected to first and second bias voltage setting means (18) and (22). In a driving circuit for a fluorescent display tube, the first and second fluorescent display tubes (10) (12) are provided.
Bias voltage value of the other fluorescent display tube (10) of the first and second fluorescent display tubes (10) (12) according to the grid voltage of one of the fluorescent display tubes (12) of Is provided with a bias voltage changing means (26).

(E) Operation As described above, according to the present invention, an electronic device having two or more fluorescent display tubes that are driven by applying an AC voltage to the filament of one fluorescent display tube is applied to the filament. In the fluorescent display tube drive circuit that commonly uses the voltage of the other, when the grid voltage of one of the fluorescent display tubes is positive, the filament current increases and the cutoff bias fluctuates. In order to prevent the problem of uneven brightness, the cutoff bias is switched only when the grid voltage of one of the fluorescent display tubes is positive to keep the apparent cutoff bias constant.

(F) Embodiment FIG. 1 shows an embodiment of the present invention. In FIG. 1, the same parts as those in FIG. 2 are designated by the same reference numerals. (24) is an OR circuit, and (Q ₁ ) is a transistor. (26) is a second bias value setting circuit, which is a current limiting resistor (R ₄ ).
And a Zener diode (D ₂ ). The breakdown voltage of this Zener diode (D ₂ ) is smaller than that of the Zener diode (D ₁ ).

 The above operation will be described.

Each grid drive signal output from the level meter grid drive circuit (14) is input to the OR circuit (24). The transistor (Q ₁ ) is driven by the output of the OR circuit (24). That is, the transistor (Q ₁ ) turns on when any one of the grids of the level meter (12) has a positive potential.

Since the smaller than the Zener diode (D ₂₎ of the breakdown voltage zener diode (D _1), when the transistor (Q ₁₎ is turned on, the breakdown voltage of the (cut-off) bias value Zener diode (D ₂₎ Depends on. If the voltage difference between the Zener diodes (D ₁ ) and (D ₂ ) is set to the same value as the ripple component (R) in Fig. 4a, the bias of the fluorescent display tube for timer when the grid of the level meter is driven. Apparently the voltage fluctuation is absorbed. That is, a good filament voltage as shown in FIG. 3 can be obtained even when the level meter is turned on. Incidentally, the variation of the cutoff bias variation due to the characteristic variation of the level meter can be absorbed by adjusting the current limiting resistor (R ₄ ) as a variable resistor.

Although the embodiment of the present invention describes only the measure against the brightness unevenness on the side of the fluorescent display tube for the timer, the measure against the brightness unevenness on the level meter side can be added with the same circuit configuration. The same is true for a plurality of fluorescent display tubes.

(G) Effect of the Invention As described above, according to the present invention, it is possible to obtain a good light emitting state without uneven brightness.

[Brief description of drawings]

FIG. 1 is a view showing an embodiment of the present invention. FIG. 2 is a diagram showing a conventional example. 3 and 4 are waveform charts. (10) ... 1st fluorescent display tube, (F ₁ ) ... filament, (T) ... transformer, (12) ... 2nd fluorescent display tube,
(F ₂ ) ... filament, (C ₁ ) (C ₂ ) ... condenser, (18) ... bias voltage setting means (first bias voltage setting means), (22) ... bias voltage adjusting means (second) Bias voltage setting means), (26) ... Second bias value setting circuit (bias voltage changing means).

Claims (1)

[Scope of utility model registration request] 1. A filament (F of a first fluorescent display tube (10).
The output of the transformer (T) is applied to 1), the output of the transformer (T) is applied to the filament (F2) of the second fluorescent display tube (12) through the capacitors (C1) and (C2), The first and second fluorescent display tubes (10) and (12) are respectively provided with first and second bias voltage setting means (18) and (22), and one of the first and second fluorescent display tubes is fluorescent. A driving circuit for a fluorescent display tube in which a grid of the display tube is driven by a grid scan signal, wherein one of the first and second fluorescent display tubes (10) (12) is In response to the grid voltage value of (12) becoming negative or becoming positive from 0, the first and second fluorescent display tubes (10) (1
A driving circuit for a fluorescent display tube, characterized by comprising bias voltage changing means (26) for changing the bias voltage value for the filament of the other fluorescent display tube (10) in (2).