KR910007496B1 - Method of measuring characteristics of cut - off of floure scendisplay elements - Google Patents

Abstract

This measuring system allows to check luminating feature of device, pick out bad items, and measure fluorescent characteristics accurately for good products by program control method. Thus it removes demerits occuring from eye measurement and hand operation, saves job flow time and labor cost. The system includes luminating detection block (10), program controller (20), driver unit (30) and interface (21). Detection block comprises photo sensor (11), signal amplifier (12), comparator (13) comparing amplified signal with reference, and 'AND' gate (14) giving logic signal to program controller. Driver unit includes power supply (31), pulse generator (32), switch box (33) and digital measuring unit (34). Driver unit (30) measures cut-off voltage and anode cut-off voltage.

Description

Method for measuring cutoff characteristics of fluorescent display device and device therefor

1 is a circuit diagram of a measuring device according to the present invention.

2 is a flowchart of program control according to the present invention.

3 is a flow chart of another embodiment embodying the flow chart of FIG.

* Explanation of symbols for main parts of the drawings

10: detection unit 11: light sensor

12 sense signal amplifier 13 comparator

14: ANDGATE 20: Program Controller

21: interface 30: drive unit

31: power supply unit 32: pulse generator

33: switch box 34: digital multi measurement unit

A: fluorescent display device I: defect inspection step

Ⅱ: Characteristic measurement stage

In the present invention, in the measurement of the cutoff characteristics of a fluorescent display device, the step of detecting the emission state of the fluorescent display device to screen out defective products that do not emit light at the beginning and precisely measuring the cutoff characteristics for non-defective products is a program control method. A fluorescent display tube for automatically executing the present invention relates to a method for measuring cutoff characteristics and an apparatus thereof.

A general fluorescent display device is configured to emit hot electrons from a filament, which is a cathode, to impinge them on a phosphor coated on an anode segment layer and to excite them, thereby providing a control grid for controlling the movement of hot electrons between the filaments and the segments. At this time, the movement of hot electrons becomes possible or impossible depending on the voltage applied to the control grid. The voltage at this point is called a cutoff voltage, and when the cutoff voltage of the grid is fixed, the hot electrons depend on the voltage applied to the anode. The movement of is controlled. As a result, the cutoff voltage is present at both the anode and the grid because it has a functional relationship between the grid voltage and the anode voltage. The cutoff characteristic of the fluorescent display device is one of important characteristics that determine the operating conditions of the device, and precise measurement results are required.

As described above, in measuring the cut-off characteristic of the fluorescent display device, the operation voltage is lowered by manual operation until the light emission is stopped while visually confirming the light emission state of the fluorescent display device, and the voltage of the anode or grid when the light emission is stopped is measured. It has been done in a primitive way.

Therefore, in the related art, the measurement conditions of each product are not considered to be constant and there is an error between individuals, and thus there is a problem that the reliability of the measurement results cannot be guaranteed, and the measurement time is long and the manpower consumption is excessively inefficient.

An object of the present invention is to enable precise measurement without personal error from defect inspection to cutoff characteristic measurement through constant program control.

It is yet another object of the present invention to provide an automated measuring device that can complete inspection of defective products and measurement of cutoff characteristics in a short time and can reduce excessive waste of manpower.

In the method of the present invention for achieving the above object, in the measurement of the cut-off characteristics of the fluorescent display device, it is determined whether the fluorescent display device emits light by setting the rated driving voltage setting and the predetermined counter value and then applying the electric shock driving voltage. If it detects but does not emit light within a certain time, the counter value is decremented by 1 to determine if the counter value is non-zero and to emit light again. It is characterized in that it consists of a characteristic measuring step of detecting whether the voltage is turned off by reducing the voltage, but not being turned off.

On the other hand, the measuring apparatus of the present invention embodying the measuring method of the present invention as described above, by detecting the light emission state on the screen side of the fluorescent display element to be measured and comparing the detected signal with a predetermined reference signal to the logic A detection unit for converting a signal, and a driving unit connected to an interface of a program controller controlled by a logic signal of the detection unit on a driving terminal side of the fluorescent display element, the power supply unit of which a program is controlled, a pulse generator, a switch box, and a digital multi-measurement unit. It is characterized by the fact that it was installed.

Embodiments of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 is a circuit diagram of the measuring device of the present invention, wherein the detection unit 10 provided on the screen side of the fluorescent display device A to be measured photoelectrically converts light emission energy of the screen and its detection signal amplifier 12 The comparison between the output of the sense signal amplifier 12 and the reference voltage is made up of a comparator 13 and an AND gate 14 which converts the voltage level output from the comparator 13 into a binary logic signal. The output of the AND gate 14 is connected to a control terminal of a program controller 20 in which a predetermined program is embedded.

On the other hand, the driving unit 30 provided on the driving terminal shaft of the fluorescent display device A includes a power supply unit 31 for supplying power, a pulse generator 32 for outputting a clock signal, and a driving terminal for the fluorescent display device A. It consists of a switch box 33 for connecting the power to the digital multi-measurement unit 34 for measuring the applied voltage (including current), each part of the drive unit 30 and the program controller 20 It is connected to the interface 21 and configured to be controlled in accordance with the execution command.

Since the apparatus of the present invention is for detecting the light emission state of the fluorescent display device A, the dark box B is used to block external light, and the fluorescent display device A and the optical sensor 11 are described in the dark box B. ) Is preferably put together. The optical sensor 11 may be a photodiode, a phototransistor, or the like, and the program controller 20 may, for example, use a control computer.

Next, the operation of the measuring apparatus according to the present invention described above will be described with reference to the flowchart shown in FIG.

First, using the external input device (not shown) of the program controller 20, each driving condition including the rated driving voltage required for driving the fluorescent display element A to be measured is set. When the counter value is set by using a function and the operation key is pressed, a predetermined energized voltage is output from the power supply unit 31 of the drive unit 30 and a clock signal is output from the pulse generator 32 at the same time. Then, the switch box 33 directly connected to the driving terminal of the fluorescent display device A receives a voltage and a clock signal from the power supply unit 31 and the pulse generator 32 so that the fluorescent display device A Opening and closing control is performed by the program controller 20 to be connected to each driving terminal. In addition, the digital multi-measurement unit 34 measures the voltage and current applied to each driving terminal of the fluorescent display device A when the program controller 20 executes the command.

Since the rated driving voltage is applied in this way, the detection unit 10 provided on the screen side of the fluorescent display element A detects whether the fluorescent display element A emits light (operation). At this time, if no light is emitted, the detection signal is not output from the optical sensor 11, so that the outputs of the detection signal amplifier 12, the comparator 13, and the end gate 14 are all low, and the low signal is transmitted to the program controller 20. Is entered. In this case, the program controller 20 decrements the counter value set as described above by one, and detects whether the value is non-zero or emits light again.

That is, the program controller 20 applies the rated drive voltage to maintain the rated drive voltage for a predetermined time (time taken until the set counter value becomes 0) when the fluorescent display device A does not emit light at the beginning. If it does not emit light within a predetermined time, it is an initial inoperable state, so that the defective inspection step I is determined to be defective.

However, when the fluorescent display device A starts to emit light, a detection signal is output from the optical sensor 11, amplified by the detection signal amplifier 12, and input to the non-inverting terminal of the comparator 13. In this way, since the voltage at the non-inverting terminal is higher than the reference voltage applied to the inverting terminal of the comparator 13 at all times, a high signal is output from the comparator 13 to control the program controller 20 through the end gate 14. Will be entered.

The program controller 20 then sends a command to the power supply unit 31 to reduce the driving voltage through the interface 21.

Therefore, the power supply unit 31 outputs a driving voltage reduced by a predetermined level and is input to the fluorescent display element A. FIG. In this way, whether the fluorescent display element A has stopped emitting light (is turned off) is also detected by the optical sensor 11, and if it is not turned off, the driving voltage is decreased again, and when it is turned off, the driving voltage at that time is measured. The characteristic measurement step (II) is performed to measure the cutoff voltage by executing a command to read and write a voltage from the measuring unit 34, and to display the voltage on a monitor (not shown).

As described above, the present invention measures the accurate cutoff characteristics by the detection unit 10 that photoelectrically converts the light emitting state of the fluorescent display device A using an optical sensor, and also performs a defect inspection for screening out defective products that are not driven at the rated driving voltage. In order to achieve the object of the present invention.

3 is a flowchart of another embodiment further embodying the measuring method of the present invention.

That is, in the characteristic measurement step of gradually reducing the driving voltage of the fluorescent display device A and measuring the cutoff characteristic, the respective terminal voltages of the fluorescent display device A, for example, the grid cutoff voltage and the anode cutoff voltage, are measured. Explain that this is possible.

As described above, according to the present invention, there is no personal error and more accurate measurement is possible, thereby ensuring the reliability of the measurement result and providing an effect of contributing to quality improvement.

In addition, the present invention is executed in a certain program control order to enable automation to solve the problem of waste, and in particular, by automatically inputting the measurement results of a number of products to the computer to enable the data processing, such as various calculations and statistics It can greatly contribute to improving efficiency.

In addition, the present invention is an extremely effective invention that is widely used for various light emitting devices such as a light emitting device as well as a fluorescent display device using the principle of discharge.

Claims (4)

In measuring the cut-off characteristic of the fluorescent display device A, after setting the rated driving voltage setting and the predetermined counter value, the rated driving voltage is applied to detect whether the fluorescent display device A emits light, Decreased the counter value by 1 to determine if the counter value is non-zero and to emit light again, and if it is 0, a defect inspection step (I), and if the fluorescent display element A starts to emit light, its driving voltage The method for measuring the cut-off characteristic of a fluorescent display device comprising the step of measuring the characteristic of turning off the light by detecting the extinguished voltage. . The method of claim 1, wherein the characteristic measuring step (II) for reducing the driving voltage of the fluorescent display device A and measuring the cutoff characteristic is performed for each driving terminal of the fluorescent display device A. Method for measuring cutoff characteristics of fluorescent display device. A detection unit 10 is provided on the screen side of the fluorescent display element A to be measured for photoelectric conversion, and a detection signal of the detection unit 10 is provided on the driving terminal side of the fluorescent display element A. The driving unit 30 connected to the controlled program controller 20 and the interface 21 to be a power control unit 31, a pulse generator 32, a switch box 33, and a digital multi-measurement unit 34, respectively, which are programmed and controlled. Apparatus for measuring cut-off characteristics of a fluorescent display device, characterized in that the installation. The comparator according to claim 3, wherein the detector 10 detects the light of the fluorescent display device A, the sensing signal amplifier 12, and a comparator comparing the output thereof with a reference voltage Vref. 13) A device for measuring cutoff characteristics of a fluorescent display device, characterized in that it comprises an end gate (14) for converting the output of the comparator (13) into a logic signal.

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