JPH0743576B2 - Power supply for fluorescent display tube - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply device for a fluorescent display tube, and in particular, a home electric appliance such as a microwave oven, an electronic jar rice cooker, etc. equipped with the fluorescent display tube as display means. A power supply device for a fluorescent display tube suitable for a product.

(Prior Art) FIG. 5 shows an example of a circuit of a power supply device for a conventional fluorescent display tube. A commercial AC power supply is connected to the primary winding of the control circuit power supply transformer 1. The secondary side of the power transformer 1 comprises a first secondary winding S ₁ and a second secondary winding S ₂ . The output of the _first secondary winding S ₁ is rectified by the bridge-type full-wave rectification circuit 2 including _four diodes D _{1 to} D _4, and smoothed by the capacitor 3. As a result, a DC voltage V _A is obtained. _A stabilized DC voltage V _D is obtained from the DC voltage V _A by the stabilization circuit 4 and the capacitor 5,
V _D is supplied to the power supply terminal of the microcomputer 6.

The microcomputer 6 has a built-in display register for controlling the display state of the fluorescent display tube 7. The display state of the fluorescent display tube 7 is controlled according to the contents of the display register. In FIG. 5, the function of the display register is schematically shown by the _two switches SW ₁ and SW ₂ . The fluorescent display tube 7 is in a non-display state when the switches SW ₁ and SW ₂ are open, and is in a display state when the switches SW ₁ and SW ₂ are closed.

The output of the second secondary winding S ₂ is half-wave rectified by the diode D ₅ and applied to the heater 73 of the fluorescent display tube 7. Further connected to the second secondary winding S ₂ is a voltage doubler rectifier circuit 8 constituted by diodes D ₆ and D ₇ and capacitors C ₂ and C ₃ . The voltage obtained by the voltage doubler rectifier circuit 8 is superimposed in such a direction as to be negative with respect to the voltage V _D (for that reason, the node R and the node Q are connected), and as a result, fluorescence is emitted. The display erasing voltage V _P applied to the anode 71 and the grid 72 of the display tube 7 is obtained.

A timing detection circuit 9 composed of a diode D ₈ and a resistor R ₃ is connected between the secondary winding S ₁ and the anode of the diode D ₁ . Diode D _{8 of the} timing detection circuit 9
A node P, which is a connection point between the resistor R ₃ and the resistor R ₃ , is connected to the microcomputer 6. The microcomputer 6
By referring to the voltage of the node P, the fluorescent display tube 7 can be brought into a display state every half cycle of the commercial AC power supply.

FIG. 6 shows an outline of the waveforms of the power supply voltage V _D , the heater voltage V _F and the display erasing voltage V _P of the microcomputer 6 in the above conventional power supply device.

(Problems to be Solved by the Invention) As household appliances such as a microwave oven and an electronic jar rice cooker become more sophisticated, various data display means are often provided. As a data display means in such home electric appliances, a fluorescent display tube for displaying multiple digits is widely used. The fluorescent display tube includes an anode that serves as a display body, a heater that emits electrons to the anode, and a grid that controls the amount of electrons that reach the anode. Is usually stretched in common from the highest digit to the lowest digit, and external terminals leading to the heater are led out from both ends of the multi-digit fluorescent display tube. Therefore, the voltage drop in the heater is often so large that it cannot be ignored as compared with the voltage between the heater and the anode. For this reason, there has been a problem that a circuit for obtaining a stable heater voltage and a display erase voltage is considerably complicated and expensive as shown in FIG.

The present invention has been made in view of such a current situation,
It is an object of the invention to provide a power supply device for a fluorescent display tube capable of obtaining a stable display erasing voltage by a relatively simple and inexpensive circuit.

(Means for Solving the Problems) A power supply device for a fluorescent display tube according to the present invention includes a first power supply device and a second power supply device.
A power supply transformer having a secondary winding, and DC power supply means for obtaining a stabilized DC voltage from the output of the first secondary winding,
Means for applying a reference voltage to the output of the second secondary winding based on the DC voltage of a predetermined portion in the DC power supply means;
A means for applying an output of the second secondary winding to the heater via the resistance, the means having a resistance connected in series to the heater of the fluorescent display tube; and an output of the second secondary winding. Means for obtaining a display erasing voltage to be applied to the grid and the anode of the fluorescent display tube by superimposing a voltage obtained by half-wave rectifying and smoothing the reference voltage on the negative direction, and the direct current And means for controlling the voltage applied to the grid and the anode, operated by means of a power supply, whereby the above-mentioned object is achieved.

(Operation) From the output of the first secondary winding of the power transformer, the DC voltage stabilized by the DC power supply means is obtained. A reference voltage based on the DC voltage of a predetermined portion of the DC power supply means is used as a reference potential for the output of the second secondary winding of the power transformer.

The output of the second secondary winding is applied to the heater of the fluorescent display tube through a resistor connected in series. The display erasing voltage applied to the anode and the grid of the fluorescent display tube is obtained by superimposing a voltage obtained by half-wave rectifying and smoothing the output of the second secondary winding on the reference voltage.

Since the amplitude of the voltage applied to the heater is smaller than the voltage across the second secondary winding due to the resistance, the display erasing voltage is always lower than the heater voltage, and the display erasing is surely performed.

(Examples) The present invention will be described below with reference to Examples.

FIG. 1 shows a circuit diagram of the first embodiment of the present invention. The control circuit power source transformer 21 includes a primary winding to which a commercial AC power source is connected, a first secondary winding S ₁ and a second secondary winding S ₂ .

A bridge-type full-wave rectifier circuit 22 including diodes D _{1 to} D ₄ is connected to the first secondary winding S ₁ . The DC voltage V _A is obtained by smoothing the output of the rectifier circuit 22 by the capacitor 23. A stabilizing circuit 24 and a capacitor 25 are connected to the subsequent stage of the rectifying circuit 22 and the capacitor 23, and a stabilized DC voltage V _D is obtained by them. Stabilized DC voltage V _D
Is supplied to the power supply terminal of.

The microcomputer 26 has a built-in display register and the like for controlling the display state of the fluorescent display tube 27. The microcomputer 26 generates a signal for controlling the anode 271 and the grid 272 of the fluorescent display tube 27 according to the contents of the display register. In FIG. 1, this control mechanism is schematically illustrated by _two switches SW ₁ and SW ₂ .

Anode of diode D ₁ of rectifier circuit 22 and first secondary winding
A timing detection circuit 29 including a diode D ₈ and a resistor R ₃ is connected between S ₁ and S ₁ . Diode D ₈ and resistance
The node P, which is a connection point with R ₃ , is a microcomputer 26.
It is connected to the. By referring to the voltage of the node P, the microcomputer 26 can control the fluorescent display tube 27 so that the display is performed every half cycle of the commercial AC power supply, which suppresses the display unevenness.

One terminal of the second secondary winding S ₂ is connected to the heater 273 of the fluorescent display tube 27 via the resistor R ₄ . Therefore, heater 2
The voltage V _F obtained by subtracting the voltage drop due to the resistor R ₄ from the voltage appearing across the secondary winding S ₂ is applied to the 73. Resistance R ₄
The heater voltage V _F can be adjusted by the value of.

Furthermore the second secondary winding the terminal of S _2, diode D ₆ to the cathode becomes the secondary winding S ₂ side is connected.
The anode of the diode D ₆ is connected to the anode 271 of the fluorescent display tube 27 and the grid 272 via the resistors R ₁ and R ₂ , respectively. A capacitor C ₅ is connected between the node R on the anode side of the diode D ₆ and the node S on the other terminal side of the secondary winding S ₂ . The output of the secondary winding S ₂ is half-wave rectified by the diode D ₆ and smoothed by the capacitor C ₅ .

A diode D ₅ is connected between the node T and the node R in the power supply circuit connected to the _first secondary winding S _{1 so} that the anode is on the node R side. Therefore, even if the capacitor C ₅ is not provided, the voltage of the node R is the voltage of one terminal of the secondary winding S ₂ to which the diode D ₆ is connected and the voltage V _A of the node T. It is the lower voltage plus the forward voltage drop of diode D ₅ or D ₆ .

The node S is connected to the node U in the circuit connected to the _first secondary winding S ₁ , and therefore the voltage V _D of the node U is in the circuit connected to the second secondary winding. It becomes the standard of the voltage of. The display erasing voltage V _P applied to the anode 271 and the grid 272 of the fluorescent display tube 27 is obtained by superposing the voltage across the capacitor C _{5 on} the voltage V _D.

The operation of this embodiment will be described with reference to FIG.

The heater voltage V _F adjusted by the resistance R ₄ is applied to the heater 273 of the fluorescent display tube 27. As shown in FIG. 2, the heater voltage V _F changes cyclically around the reference voltage V _D. The temperature of the heater 273 rises due to the application of voltage,
Electrons are emitted.

The display erasing voltage V _P becomes lower than the voltage V _{D as} can be seen from the direction of the diode D ₆ . Further, the size of the heater voltage V _F is smaller than the voltage appearing at both ends of the secondary winding S ₂ by the amount of the voltage drop due to the resistor R _4, so that the display erasing voltage
V _P, even at lower period than the heater voltage V _F is the voltage V _D, is lower than the heater voltage V _F. In this way, the display erasing voltage V _P is always kept at a level lower than the heater voltage V _F , and the display erasing of the fluorescent display tube 27 is surely performed. Note that what is indicated in broken lines in Figure 2, is a waveform of the in voltage V _P if the capacitor C ₅ is not provided, as can be seen from this waveform, the capacitor C ₅ is provided if If not, the voltage V _P will always be lower than the voltage V _F.

In this embodiment, the switches SW ₁ and S of the microcomputer 26 are operated during the half cycle in which the heater voltage V _F is at a high level.
W ₂ is closed, and the potentials of the anode 271 and the grid 272 rise to a ground potential that is sufficiently higher than the potential of the heater 273. Therefore, the electrons from the heater 273 reach the anode 271, and the fluorescent substance on the anode 271 emits light to perform display.

FIG. 3 shows a circuit diagram of the second embodiment of the present invention. The configuration of the present embodiment is the same as that of the first embodiment except for the circuit connected to the second secondary winding S ₂ , and therefore, the corresponding parts have the first part.
The same reference numerals as those in the figure are given and the description thereof is omitted.

Of the circuits connected to the second secondary winding S ₂ , the fluorescent display tube 27
The portion for applying a voltage to the heater 273 is similar to that of the first embodiment.

At one terminal of the second secondary winding S ₂ , the cathode is connected to the second
The diode D ₆ is connected to the side of the secondary winding S ₂ . Node R on the anode side of diode D ₆ and secondary winding S ₂
A capacitor C ₅ is connected to the node S on the other terminal side of the. The node S is connected to the node T in the power supply circuit connected to the _first secondary winding S ₁ . Therefore, the voltage V _A serves as a reference for the voltage in the circuit connected to the secondary winding S ₂ . The output of the second secondary winding S ₂ is half-wave rectified by the diode D ₆ and smoothed by the capacitor C ₅ . The display erasing voltage V _P is obtained by superimposing the voltage across the capacitor C _{5 on} the voltage V _A. The node S
To the node U connected to the microcomputer 26.
It is also possible to obtain a display erasing voltage V _P by connecting to the capacitor C ₅ and superposing the voltage across the capacitor C _{5 on} the voltage V _D.

In this embodiment, the circuit connected to the second secondary winding S ₂ requires only one resistor, one diode and one capacitor, and the circuit configuration is simpler than in the first embodiment. is there.

FIG. 4 shows a voltage waveform of each part in the present embodiment.
As is apparent from the figure, the display erasing voltage V _P is always kept lower than the heater voltage V _F also in this embodiment. Therefore, when the switches SW ₁ and SW ₂ are open, the display is surely erased. The broken line in FIG. 4 is the capacitor.
The display erasing voltage V _P when C ₅ is not provided is shown.

(Effects of the Invention) According to the present invention, a fluorescent display tube that can obtain a stable display erasing voltage with a simpler and cheaper circuit configuration than the conventional one and can stably operate the fluorescent display tube. Power supply device is provided.

[Brief description of drawings]

FIG. 1 is a circuit diagram of the first embodiment of the present invention, and FIG.
Of the voltage waveform of each part in the embodiment of the present invention, FIG. 3 is a circuit diagram of the second embodiment of the present invention, and FIG. 4 is a voltage waveform of each part of the second embodiment. 5 shows an outline of FIG.
FIG. 6 is a circuit diagram of a conventional example, and FIG. 6 is a diagram showing an outline of voltage waveforms of respective parts in the conventional example. 21 ... Control power transformer, 26 ... Microcomputer, 27 ... Fluorescent display tube, 271 ... Fluorescent display tube anode, 272 ... Fluorescent display tube grid, 273 ... Fluorescent display tube heater, D ₁ , D ₂ , D ₃ , D ₄ , D ₅ , D ₆ ... Diode, R ₄
...... Resistor, C ₁ , C ₄ , C ₅ ...... Capacitor, S ₁ ...... First 2
Winding, S ₂ ...... the second secondary winding.

Claims (1)

[Claims] 1. A power supply device for a fluorescent display tube, comprising: a power supply transformer having first and second secondary windings; and a direct current stabilized from an output of the first secondary winding. DC power supply means for obtaining a voltage, means for giving a reference voltage to the output of the second secondary winding based on the DC voltage of a predetermined portion in the DC power supply means, and a series of heaters of the fluorescent display tube. Has a resistor connected to
Means for applying the output of the second secondary winding to the heater through the resistor; and a voltage obtained by half-wave rectifying and smoothing the output of the second secondary winding, the reference Means for obtaining a display erasing voltage to be applied to the grid and the anode of the fluorescent display tube by superimposing the voltage in a negative direction, and a voltage applied to the grid and the anode operated by the DC power supply means And a means for controlling the power supply for the fluorescent display tube.