KR100358096B1 - Degaussing coil ability test apparatus and method - Google Patents

Abstract

Disclosed is a performance testing apparatus and method for degaussing coils that allows not only the determination of degaussing coils but also the overall characteristics of degaussing through degaussing tests. The magnetic field sensing unit senses the induced electromotive force from the degaussing coil. The sensed electromotive force is converted into a digital signal through a signal processor and an AD converter. The performance tester analyzes the digital signal using numerical analysis tools and current waveforms, and displays the analyzed results in a graph, so that not only the determination of the degaussing coil but also the overall characteristics of the degaussing can be examined. do.

Description

Degaussing coil ability test apparatus and method

The present invention relates to an apparatus and a method for testing the performance of a degaussing coil, and more particularly, to an apparatus and a method for testing the performance of a degaussing coil installed in a CRT or monitor screen around a substantially rectangular plate in a process. will be.

When a television or a monitor has not been operated for a long time and is operated, a picture quality problem such as tilting or tilting the screen of the CRT may occur under the influence of the geomagnetic field. In order to prevent color purity deterioration due to the influence of geomagnetism or external magnetic field on such televisions and monitors (hereinafter referred to as 'TV'), a circuit for removing the magnetism of the shadow mask of the water pipe and the cabinet is degaussing. It is a degaussing coil.

As an apparatus for testing degaussing in the process, conventionally, the induced electromotive force generated from the degaussing coil of the object to be measured is sensed and compared with the steady-state voltage value, and as a result, the degaussing of the degaussing coil is determined. In addition, an apparatus for recognizing the change of the screen over time using a camera and comparing the recognized result with the state before degaussing is also used.

1 is a block diagram illustrating a degaussing test apparatus using an induced electromotive force according to the prior art. Referring to FIG. 1, a conventional degaussing test apparatus for supplying power to a television 10 equipped with a degaussing coil (not shown) and to supply electric power to the television 10 so that an electric field is formed in the degaussing coil. It has a power supply 11 and a conveyor 12 for transporting the television 10 to a specific individual workplace. In addition, the degaussing test apparatus includes an electric field sensing unit 13 for sensing the induced electromotive force generated from the degaussing coil of the television 10 and a rectifier 15 for directing the induced electromotive force sensed by the electric field sensing unit 13. ), A judging unit 17 for comparing the degaussing coil's steady state value by comparing the voltage value of the DC-induced electromotive force with the induction electromotive force of the degaussing coil shown by a typical experiment; The display unit 19 further has a display unit 19 for displaying both of the degaussing coils determined by the determination unit 17. Although the degaussing coil is not shown, a winding is formed several times on the inner surface of the television 10 in the circumferential direction of the edge of the square screen.

In the degaussing test according to the related art shown in FIG. 1, first, a worker uses a power supply unit 11 to a television 10 that has been moved to a work area of a worker for degaussing by a conveyor 12. Apply power. At this time, the television 10 displays a predetermined image on the screen. The electric field sensing unit 13 detects induced electromotive force generated from the degaussing coil of the television 10. The induced electromotive force is converted into direct current by the rectifier 15 and input to the determination unit 17. The determination unit 17 compares the voltage value with the operator's set voltage value (or an experimental voltage value that can distinguish the degaussing coil operation) to determine the degaussing coil. In this way, if the degaussing coil is passed or not, the display unit 17 displays the determined fact so that the operator is informed. Therefore, the operator sees the state shown on the display unit 17 to distinguish whether the degaussing coil is good or bad.

2 is a block diagram illustrating a degaussing test apparatus using a camera according to the prior art. This device is a device for recognizing the change of the screen over time using a camera, and comparing the recognized result with the state before degaussing to determine the degaussing coil.

A conventional degaussing test apparatus using a camera includes a television 20 equipped with a degaussing coil (not shown), and a power supply unit supplying power to the television 20 so that an electric field is formed in the degaussing coil ( 21 and a conveyor 23 for transporting the television 20 to a specific individual workplace. In addition, the pattern generator 28 for producing a test image, the camera 23 for detecting the screen change of the television 20, and a frame grabber for storing the image detected by the camera 23 A grabber 25 and a judging unit 27 for deciding whether or not the degaussing coil is judged by comparing the image sensed by the camera 23 with the test image, and the degaussing coil determined by the judging unit 27. The display unit 29 has a display unit 29 for displaying both sides of the display unit.

In the conventional degaussing test according to FIG. 2, the operator first applies power to the television 20, which has been transferred to the operator's work area for the degaussing test by the conveyor 22, through the power supply unit 21. do. At the same time that power is applied, the pattern generator 28 generates a test image. The test image is a normal image without degaussing. The television 20 converts the image generated by the pattern generator 28 into a degaussing state. The camera 23 detects a process in which the test image generated by the pattern generator 28 is degassed and is harmonized. The frame grabber 25 stores the input image in a storage place for image storage at a speed scanned by the camera 23 about once every 30 seconds. The determination unit 27 compares the test image generated by the pattern generator 28 with the image detected by the camera 23 to determine whether degaussing is normally performed. If it is determined that degaussing is normally performed, it is determined that the degaussing coil is good.

By the way, in the conventional degaussing test apparatus according to Figs. 1 and 2, the induced electromotive force generated from the degaussing coil is rectified to make a determination using only the peak value of the voltage, or the image of the screen before and after the degaussing operation. Determining and determining the change in the screen when degaussing is performed, the component characteristics and the de-essential thermistor (PTC) or negative temperature coefficient (NTC) There is a problem that it is not possible to perform the overall characteristic test of the Gaussing.

The present invention was devised to solve the above problems, a degaussing test apparatus capable of inspecting the overall characteristics of the degauss and component characteristics that PTC or NTC should have from a television equipped with a degaussing coil. And to provide a method.

1 is a block diagram showing a degaussing test apparatus using an induced electromotive force according to the prior art,

2 is a block diagram showing a degaussing test apparatus using a camera according to the prior art,

3 is a schematic diagram showing an apparatus for testing performance of a degaussing coil according to a first embodiment of the present invention;

4 is a schematic diagram showing an apparatus for testing performance of a degaussing coil according to a second embodiment of the present invention;

5 is a schematic diagram showing an apparatus for testing performance of a degaussing coil according to a third embodiment of the present invention; and

6 is a flowchart illustrating a performance test method of a degaussing coil according to the present invention.

Explanation of symbols on the main parts of the drawings

10, 20, 30, 40, 50: TV 12, 22, 32, 42, 52: Conveyor

13, 31, 41, 51: electric field sensing unit 33, 43, 53: signal processing unit

33a, 43a, 53a: Amplifiers 33b, 43b, 53b: Signal Distribution

35, 45, 55: AD converter 37, 47, 57: performance tester

46: remote control board 56: I / O board

59: display unit

In order to achieve the above object, a degaussing test apparatus according to the present invention includes: an electric field sensing unit sensing an induced electromotive force generated from a degaussing coil; A signal processor which receives and processes the induced electromotive force sensed by the electric field sensing unit to digitize it; An AD converter which receives the analog signal processed by the signal processor and converts the analog signal into a digital signal; And a performance checker that analyzes the pattern of the digital signal to check the performance of the degaussing coil.

The above object is a performance test method of a degaussing coil, the method comprising: converting an electromotive force induced in a degaussing coil of an object to be measured into a digital signal; And by using at least one of the current, the FFT numerical analysis tool, the expansive numerical analysis tool, and the numerical analysis tool linearly extending the exponential function for the sensed induced electromotive force. Iii) a method of testing the performance of a degaussing coil comprising determining and determining the degaussing properties of the object to be measured.

Here, the electric field sensing unit is preferably made of a sensing coil using an inductive material. The signal processing unit includes an amplifier and a signal distribution unit. The amplification factor of the amplifier is preferably about 300 to 1 in consideration of the sensitivity of the signal to be sensed and the allowable range of the signal processor. The signal distribution unit preferably comprises a voltage distribution circuit that alternates the induced electromotive force sensed by the electric field sensing unit with respect to the midpoint voltage.

3 is a schematic diagram of an apparatus for testing performance of a degaussing coil according to a first embodiment of the present invention. The performance test apparatus of the degaussing coil according to the first embodiment of the present invention includes an electric field sensing unit 31, a signal processing unit 33, an AD converter 35, and a performance testing unit 37. Here, the signal processor 33 is composed of an amplifier 33a and a signal distributor 33b. In addition, the signal processor 33 according to the present embodiment connects one end of a circuit in which the resistor R and the capacitor C ₁ are connected in parallel and one end of a circuit in which the other equivalent resistor R and the other equivalent capacitor C ₁ are connected in parallel. It is composed of a circuit connecting one end and the other end of capacitor C ₀ to each other end, and connecting both ends of the amplifier output side to both ends of capacitor C ₀ .

The television 30 to be measured is conveyed by the conveyor 32 to the operator's work area for the degaussing test. When power is applied to the television 30 by an operator, the electric field sensing unit 31 senses induced electromotive force generated from the degaussing coil in the television 30. The amplifier 33a in the signal processor 33 amplifies the induced electromotive force sensed by the electric field sensing unit 31. The signal amplified by the amplifier 33a, that is, the amplified induced electromotive force, is input to the signal distributor 33b in the signal processor 33.

The capacitor C ₀ of the signal distribution unit 33b serves as a noise filter that allows only the rated voltage or less. In addition, each resistor R is composed of a voltage distribution circuit applying the same voltage, and each equivalent capacitor C ₁ connected in parallel to each resistor R reduces the voltage error applied to each equivalent resistor R. Therefore, noise is removed by the noise filter C ₀ from the signal input to the signal distribution section 33b, and the same voltage is applied to each of the equivalent resistors R. In other words, the signal input to the signal distribution section 33b flows alternately with respect to the midpoint voltage.

The analog signal alternated by the signal distributor 33b is digitally converted by the AD converter 35 and exists in the form of data that the performance tester 37 is easy to analyze. The AD converter 35 is connected to the performance tester 37 through a PCI bus (Peripheral Component Interconnect). The performance tester 37 generally refers to a personal computer.

The performance inspection unit 37 analyzes the pattern of the digital signal received from the AD conversion unit to determine the degaussing of the degaussing coil, and examines the characteristics of the parts that PTC and NTC should have and the overall degaussing of degaussing. Run Execution of the performance inspection unit 37 is implemented by the performance test method of the degaussing coil to be described later.

4 is a schematic diagram of a performance test apparatus for a degaussing coil according to a second embodiment of the present invention. In the present embodiment, the television 40, the electric field sensing unit 41, the conveyor 42, the signal processing unit 43, the amplifier 43a, the signal distribution unit 43b, the AD conversion unit 45, and the performance inspection unit Reference numeral 47 is the same as in the above-described first embodiment. In the present embodiment, the performance test apparatus of the degaussing coil further includes a remote control board 46. The remote control board 46 is connected to the performance test unit 47 through the PCI bus.

The remote control board 46 enables the control of the object to be measured at a long distance. When the operator performing the degaussing testing inputs the on / off information of the measured object, the frequency change information, etc. to the performance inspection unit 47, the remote control board 46 is input by the operator from the performance inspection unit 47 through the PCI bus. Receive the information. The remote control board 46 retrieves a remote control code corresponding to the received information and outputs the remote control code to an information retrieval light-emitting diode (IR-LED) installed in the object to be measured. The remote control board 46 searches for the remote control code and outputs it to the object to be measured wirelessly. Thus, when the setting of the television 40 as the measured object is completed, the operator can control the on / off of the measured object at a long distance, and also easily measure the change of the degaussing according to the change of the state of the measured object at a long distance. You can do it.

5 is a schematic diagram of an apparatus for testing performance of a degaussing coil according to a third embodiment of the present invention. In the present embodiment, the television 50, the electric field sensing unit 51, the conveyor 52, the signal processing unit 53, the amplifier 53a, the signal distribution unit 53b, the AD conversion unit 55, and the performance inspection unit Reference numeral 57 is the same as in the first embodiment described above. In the present embodiment, the performance test apparatus of the degaussing coil includes an I / O board 56 which outputs a result of the determination of the quality of the object to be measured and a display unit 59 which displays the result received from the I / O board 56. It is configured to further include. The I / O board 56 is connected to the performance test unit 57 through the PCI bus.

When the performance inspection unit 57 receives the digital signal from the A / D conversion unit 55 and performs the determination of degaussing on the degaussing coil, the I / O board 56 receives the result of the determination of the acceptance from the performance inspection unit 57. Is received and provided to the display unit 59. The display unit 59 displays the result of the determination of good value received from the I / O board 56 for the operator to see.

In this way, the operator can know the result of the judgment on the object to be measured without looking at the performance inspection unit 57.

6 is a flowchart illustrating a performance test method of a degaussing coil according to the present invention. The performance test method of the degaussing coil according to the present invention includes the steps of: converting electromotive force induced in the degaussing coil to be measured into a digital signal (S107); And by using at least one of the current, the FFT numerical analysis tool, the expansive numerical analysis tool, and the numerical analysis tool linearly extending the exponential function for the sensed induced electromotive force. Iii) examining the determination and degaussing characteristic of the object to be measured (S113).

First, when the measured object is transferred to the conveyor (S101), the degaussing coil's performance test apparatus detects the setting of the measured object (S103), and reads the product information on the measured object from the reading means of the measured object. do. The reading means of the object to be measured is generally implemented by a barcode. Product information read through the reading means is input to the performance inspection unit. After the product information on the object to be input is input, when power is applied to the object to be measured by the operator or the remote control board, a predetermined screen is implemented on the object to be measured. At this time, power is applied to the degaussing coil installed inside the object under test, and the geomagnetic field formed in the CRT is destroyed by the induced electromotive force.

The magnetic field sensing unit senses the induced electromotive force generated from the degaussing coil (S105). The induced electromotive force sensed by the magnetic field sensing unit is amplified by an amplifier in the signal processing unit. The amplified signal is removed with noise by a noise filter, and is alternated with a positive signal with respect to the midpoint voltage through the signal distribution unit. The AD converter receives the alternating analog signals, converts them into digital signals, and outputs the converted digital signals to the performance inspection unit (S107).

The performance inspecting unit digitizes the digital signal inputted from the AD converting unit so as to easily analyze the digital signal (S109). The performance inspector analyzes the degaussing of the object to be measured using a digitized digital signal, using an FFT (Fast Furie Transform) numerical analysis tool, an expansive numerical analysis tool, or a numerical analysis tool that linearly crosses an exponential function (S111). In addition, the degaussing of the degaussing coil and the overall characteristics of the degaussing are examined (S113). Such a process of checking the degaussing of the degaussing coil and the overall characteristics of the degaussing is displayed as a graph of the performance analysis pattern on the monitor of the performance inspection unit so as to be easily understood by the operator. Graphs of performance analysis patterns include V _PP (peak current peak through degaussing coil), degaussing frequency (frequency used for degaussing), envelopes or slopes (natural decaying wave during degaussing). Information on the slope of the device, the on time (the proper degaussing time), the off time (the decreasing time; The format of the graph may include a current wave graph for the sensed electromotive force, a graph for the peak value of the sensing waveform, a graph for the frequency of the sensing waveform, an envelope graph, and the like.

In addition, the performance tester compares the analyzed V _PP , the degaussing frequency, the envelope or slope, the on time, the off time, and the gain of a particular point with each of the stored titration values obtained by conventional experiments. If one or more of the analyzed results do not reach the corresponding appropriate value, the performance inspection unit makes a bad decision. When each of the analyzed results satisfies the corresponding appropriate value, good quality judgment is performed (S115). At this time, when the measured object is determined as good quality, the performance inspecting unit accumulates the result of the good quality determination of the measured object on the histogram graph and displays the accumulated histogram graph on the monitor of the performance inspecting unit (S117). The histogram graph provides good manufacturing statistics and degaussing characterization statistics for the entire product for which the performance of the degaussing coil is measured.

The result of the good judgment is not only displayed on the monitor of the performance inspector, but also input to the display through the I / O board connected through the performance inspector and the PCI bus. The display unit displays the determination result of the defect so that the worker can see it (S119). Alternatively, the display unit may be implemented through means such as an alarm or a lamp. In this way, the operator can quickly respond to the failure.

In addition, by changing the remote control code of the remote control board connected to the performance test unit and the PCI bus, it is possible to check the degaussing change of the object under test. It is mainly used to repeat the inspection of the same measurement through on / off control of the measurement object, but it is also possible to inspect the degaussing change state by changing the frequency. As a result, various tests can be performed on the same object to be measured, thereby obtaining more accurate results according to the increase in the repeatability and diversity of the tests.

In this way, by using a mathematical analysis method rather than a simple comparison concept, it is possible not only to determine whether the degaussing coil is defective, but also to inspect the part characteristics that PTC or NTC must have, and the overall degaussing characteristics. .

In the present invention, the signal distribution unit is constituted by a voltage divider circuit, but is not limited thereto and may be constituted by a current divider circuit.

In the present invention, the object to be measured is a television. However, the object to be measured can be measured by a computer monitor, a cathode ray tube (CRT) or a color picture tube (CPT).

In addition, in the present invention, in order to implement the performance test method of the degaussing coil, the FFT numerical analysis tool, the expansive numerical analysis tool, the numerical analysis tool which linearly crosses the exponential function, and the like are used. Is not limited to the above.

By constructing a digital analysis system using the magnetic field sensing unit and the AD conversion unit, and introducing a mathematical analysis method from the simple comparison concept, it is necessary to have PTC or NTC as well as to determine the degaussing coil of TVs. Component properties and overall degaussing properties can also be examined.

Claims (11)

An electric field sensing unit sensing an induced electromotive force generated from the degaussing coil; A signal processing unit for processing to receive and digitize the induced electromotive force sensed by the electric field sensing unit; An AD converter which receives the analog signal processed by the signal processor and converts the analog signal into a digital signal; And And a performance tester which analyzes the pattern of the digital signal to check the performance of the degaussing coil. The method of claim 1, The electric field sensing unit, the performance test apparatus of the degaussing coil, characterized in that it comprises a sensing coil using an inductive material. The method of claim 1, The signal processing unit, An amplifier for amplifying and outputting the induced electromotive force received from the electric field sensing unit; And And a signal distribution unit alternately alternating the signal output from the amplifier with respect to the midpoint voltage. The method of claim 3, wherein The signal distribution unit, And a noise filter for removing the noise by receiving the signal output from the amplifier. The method of claim 4, wherein The performance test unit, the performance test apparatus of the degaussing coil further comprises a remote control board to enable remote control of at least one of the on / off, the frequency of the object to be measured. The method of claim 5, The remote control board outputs a remote control code corresponding to the measured object based on the change information on at least one of the on / off and the frequency of the measured object input by the operator to the performance inspection unit to perform remote control. Degaussing coil performance test device, characterized in that. The method of claim 4, wherein The performance test unit, An I / O board for outputting a result of a judgment on the object to be measured; And And a display unit which displays a result received from the I / O board. Converting the electromotive force induced in the degaussing coil of the object to be measured into a digital signal; And By using at least one of an FFT numerical analysis tool, an exponential numerical analysis tool, and a numerical analysis tool that linearly crosses an exponential function, the determination of the quantity of degaussing coil and the measurement of the object to be measured are performed on the digital signal. A method for testing the performance of a degaussing coil comprising the step of inspecting a Gaussian characteristic. The method of claim 8, The conversion step, Amplifying a signal received from the magnetic field sensing unit; Alternating the amplified signal with respect to a midpoint voltage; And And digitizing the alternating signal into data that is easy to be analyzed by a performance inspector. The method of claim 8, And displaying the degaussing result and the degaussing characteristic on a monitor of a performance inspecting unit. The method of claim 10, The displaying step may include a current, an FFT numerical analysis tool, an exponential numerical analysis tool, and an exponential function for the sensed induced electromotive force used for determining the degaussing coil of the degaussing coil and inspecting the degaussing characteristic of the measured object. Graphically displaying at least one of a current waveform for an induced electromotive force, a frequency of a sensing waveform, an envelope of a sensing waveform, and a slope of a naturally decreasing wave upon degaussing based on at least one of the linearly analyzing numerical analysis tools Degaussing coil performance test method comprising a.