RU2201598C2 - Procedure testing internal electric networks of electrodes of electronic devices - Google Patents

Abstract

FIELD: electrical engineering, equipment testing electronic devices. SUBSTANCE: parameters of test in accordance with given procedure testing internal electric networks of electronic device with internal and external current-conducting surfaces are determined by means of additional electrode by way of successive positioning of additional electrode in two adjacent zones in . area of internal network of tested electrode of electronic device. Obtained values of parameters are compared with parameter-criterion established beforehand. Frequency F of alternating voltage fed to outer lead of internal electrode is chosen from relation 2/RC≥F≥1/RC, where R is physically specified value of resistance of internal network of tested electrode; C is physically specified value of capacitance between internal currentconducting network of tested electrode and external current-conducting surface of device. EFFECT: increased accuracy of diagnostics of device. 3 dwg

Description

 The invention relates to electronic equipment and can find application for testing high-voltage electrovacuum devices, for example broken picture tubes, on the quality condition of internal electrical circuits and determining the location of their damage.

There is a method of testing the suitability for subsequent work in a failed (out of order) picture tube as a high-voltage voltage divider of an intra-vacuum high-resistance resistor, the potentials from the taps (intermediate leads) of which are supplied to the electrodes of an electron-optical color tube system [1]. The method consists in two consecutive measurements of the current values (I ₁ and I ₂ ) in the circuit of a high-resistance resistor through a divider at its low-voltage end at two potential U (constant voltage) at its high-voltage end, relatively low U ₁ and high U ₂ . Then, the value of the expression I ₂ -I ₁ • U ₂ / U ₁ is determined, which is used to judge the integrity of the high-resistance resistor located inside the vacuum shell in close proximity to the electron-optical tube system. This method involves the presence of a high-resistance resistor inside the electrovacuum device with intermediate leads connected to the electrodes of the electron-optical system, the extreme leads of which, high-voltage and low-voltage, are connected to the external terminals of the tube. In this case, the measuring circuit that implements this method is formed by sequentially switching on the source of the test voltage, the tested high-resistance resistor and current meter. A prerequisite is that the tested resistor has two leads connected to the measuring circuit. However, most electrovacuum devices, including color picture tubes, for connecting to external circuits have only one output from each electrode located inside the shell, which excludes the possibility of checking them by this method. In addition, this method determines only the suitability of the resistor connected by its intermediate terminals to the electrodes of the electron-optical system, but does not determine whether these terminals are connected to the internal electrodes. At the same time, it is possible that the test will establish the suitability of the resistor, but if there is no connection of its intermediate leads to one of the electrodes of the electron-optical tube system, the latter will not actually work.

 Closest to the combination of essential features is a method of monitoring the suitability of the internal electrical circuits of the electrodes of the electrovacuum device formed by internal electrical circuits and external terminals [2]. In this method, the voltage of a given amplitude with a frequency F is applied to the external terminals of the electrodes of the device under test through a series-connected indicator (a neon lamp) and a current-limiting resistor. At the same time, analyzing the brightness of the indicator, which can be used as another measuring device, evaluate the degree of operability (serviceability) of internal electrical circuits. This method allows you to determine the presence in the circuits of the electrodes of electro-vacuum devices breaks and short circuits that affect the ability of these devices to work in electrical modes specified technologically. However, in high-voltage electrovacuum devices, in particular color tubes, which have conductive coatings (surfaces) deposited on the inner and outer surfaces of the glass shell (balloon), there are several areas where these surfaces come into contact with each other or with other conductive elements of the electrode structure (anode output , contact springs, ram mask assembly, clamps of the ram mask assembly) of the device. All of these elements form an electrical circuit of the internal electrode of the device, in particular the anode, the elements of which in the operating mode must be under the same potential supplied to it through an external output. Violation of the electrical connection between the internal conductive coatings and other conductive elements of the electrode structure leads to loss of operability of the device. This leads to increased requirements for the integrity of the specified circuit. However, in a known manner it is impossible to determine the position of the fault region in the electrode circuit (break) inside the device, since the indication (control) of the internal electrical circuits occurs by simply determining the integrity of the circuit formed by the serial connection of the internal conductive elements of the electrode.

 The basis of the invention is the solution of the technical problem of control (testing) of the electrical circuits of electrovacuum devices, mainly color picture tubes formed by internal conductive coatings and other conductive structural elements associated with the output terminal (anode terminal). These chains have significant areas, consist of conductive coatings that are heterogeneous in composition of the material, which are deposited on the inner surfaces of the glass parts (tube, cone, screen) of the tube. All internal conductive surfaces are electrically connected to each other and to the external terminal using various design and technological solutions. As a result, inaccessible areas are formed to control the electrical integrity of the electrode. Such testing should determine the electrical properties of the circuits and the location of the zone of their likely damage. However, the known method does not completely solve the problem of testing the entire electrical circuit of the internal electrode due to the inability to obtain information about the detailed malfunction of the tube and the inability to assess the performance of a particular section of the circuit under test.

 The solution to this problem is relevant when carrying out repair work on the restoration of failed color picture tubes, since timely information received on the violation of the integrity of the internal circuits of the electrodes makes it possible to decide on the feasibility of repairing the device. The effectiveness of the work to identify the cause of failure of a particular device and reduce the cost of its repair depends on the accuracy of individual diagnostics.

 To solve the problem in a known method for monitoring the internal electrical circuits of the electrodes of an electrovacuum device with internal and external conductive surfaces, in which the external terminals of the internal electrodes are supplied with an alternating voltage of a given amplitude with a frequency F to obtain the control parameters displayed on the measuring device, after which they are carried out analysis, according to the invention, form a capacitive coupling with the internal electrode, for which purpose on the outer surface of the device, free of of conductive surfaces, place an additional electrode electrically connected to the measuring device, and conduct two consecutive measurements in two adjacent zones in the region of the internal electric circuit of the electrode to be monitored, calculate the difference between the first and second results of measurements of electrical signals, compare the obtained value with a predetermined reference value ( parameter-criterion) and, based on the results of comparison, draw conclusions about the suitability of the evaluated section of the internal electrical circuit, and the frequency F is determined from the ratio 2 / RC≥F≥1 / RC, where R is the structurally specified resistance value for the internal circuit of the electrode being monitored; C-structurally set value of the capacitance between the internal conductive circuit of the controlled electrode and the external conductive surface of the device.

 With this method of monitoring the integrity of the internal circuits of the device, in particular, it is possible to determine the local zone of their violation. The use of an additional external electrode connected to the meter and forming a capacitive coupling through the glass of the shell with the internal conductive coating allows one to analyze the magnitude of the electric signal in individual sections (zones) of the internal conductive coating. In this case, the area of the additional electrode forming the capacitive coupling of the measuring device with the internal electrode is selected taking into account the known inversely proportional dependence of the influence of the communication capacitance on the accuracy of voltage measurements on the controlled electrode when applying an alternating voltage to the latter. The sequential measurement of electrical signals in two adjacent zones in the region of the internal circuit of the electrode, followed by the mutual subtraction of the obtained values of the control parameters, for example, voltage, and comparing the result with a predetermined parameter-criterion makes it possible to make an unambiguous decision on the suitability of the tested section of the internal electric circuit of the kinescope electrode for its further use. Determination of the value of the parameter-criterion is carried out by preliminary measurement in the specified zones of the device shell in the area of the internal circuits of the electrode of the magnitude of the electrical signal on several known-good devices with subsequent averaging of the obtained values. The choice of the frequency F of the alternating voltage supplied to the device under test, according to a given ratio, is associated with the parameters of the low-pass filter formed by the structural elements of the device. A simplified equivalent circuit of the mentioned filter is shown in Fig. 1, where X1 is the output of the picture tube anode, X2 is the external conductive elements, R1 is the resistance of the transition region from the anode output to the internal conductive coating of the cone, C1 is the capacitor formed by the external and internal conductive coatings of the kinescope cone , R2 is the resistance of the contact area of the internal conductive coating of the cone with the contact spring of the screen-mask assembly, C2 is the capacitance between the internal conductive coating of the screen and the bandage (explosion itnym device), R3 - resistance of the transition region from the retainer to the internal conducting screen coating, C3 - capacitance between the inner conductive screen coating and conductive coating cone. The presence of a defect in the internal conductive coating leads to a change in the resistance value in the specified circuit, and therefore to a change in the cutoff frequency of the low-pass filter and the redistribution of the alternating voltage between the filter elements, which is recorded by the measuring device.

 A comparison of these distinctive features of the proposed technical solution with the prototype allows us to establish compliance with its criterion of "novelty."

 The essence of the proposed technical solution is not obvious, since the use in the method of a set of features that provide the creation through the glass of the shell of the tested device of capacitive coupling with the internal circuit of the controlled electrode, the receipt of electrical signals that carry information about the electrical state of the internal circuit of the controlled electrode in hard-to-reach measurement zones, make up a new , a previously unknown set of features that allow not only to assess the quality condition, but also specify the places of violation of internal electrical connections, including without devacuating the device.

 All this allows us to argue that the proposed technical solution has new properties and, therefore, inventive step.

 The industrial applicability of the method is not in doubt, since at present one of the variants of the device that implements this method is used in small-scale production, repairing color picture tubes.

 An embodiment of the method in the conditions for the production of color picture tubes is illustrated in figures 1-3. Figure 2 shows a fragment of the section of the tube of the kinescope 1 with internal conductive circuits of the anode, structurally made in the form of conductive coatings, which shows: the external terminal 2 of the anode, the additional electrode 3 in two working positions I and II, the cone 4, the external conductive coating 5, the inner conductive coating 6 of the cone 4, the shield 7, the inner conductive coating 8 of the shield 7, the contact spring 9, an explosion-proof device (band) 10 and potentially unreliable sections 11 of the internal electrical circuits of the anode. Such sections, in particular, are the junction of the terminal 2 of the anode with the inner conductive coating 6 of the cone 4, the junction of the inner conductive coating 6 of the cone 4 with the contact spring 9.

 In FIG. 3 shows a diagram of one embodiment of the device, with which the proposed method is tested to control the internal circuit of the anode of the television picture tubes of a color image.

 The device comprises a generator 12, the output of which is connected to an AC voltage amplitude stabilizer 13, the output of which is connected to the terminal of the anode 2 (external terminal of the internal electrode) of the tested picture tube 1. An additional electrode 3 is electrically connected to the input of the amplifier 14, the output of which is connected to the input of the amplitude detector 15 The output of the amplitude detector 15 is connected to an indicator 16 of the electric signal - microammeter. Elements 14, 15 and 16 form a measuring device 17. The external conductive coating 5 and the band 10 of the tube 1 are electrically connected to a common wire of the power source 18, meter 17 and alternating voltage generator 12.

 The proposed method is as follows.

 The voltage from the power source 18, which uses a 9V battery, is supplied to the circuit elements of a device that implements the method. An alternating voltage with a frequency of F = 100 kHz and an amplitude of 6 V from the generator 12, made on the integral timer KR1006VI1, is supplied through the amplitude stabilizer 13, which is a voltage limiter on the LEDs, to the output of the anode 2 of the picture tube 1. The external conductive coating 5 and the bandage 10 of the picture tube 1 are connected with a common wire of the power source 18. An additional electrode 3, equipped with an insulating gasket (not shown), is placed on the outer surface of the tube of the tube 1, free of external conductive coating 5, in zone I, as a result Therefore, a capacitive coupling is formed between the internal conductive coating 6 (FIG. 2) and the measuring device 17. An alternating voltage from the additional electrode 3 is supplied to the measuring device 17, which registers the signal value of the first monitoring parameter. Then the additional electrode 3 is placed in zone II of the tube 1, free of external conductive coating 5, and located, for example, at a distance of 3-5 cm from zone 1, after which the second parameter is recorded using the measuring device 17. Then, the difference between the first and second parameter values is calculated and, by comparison with a predetermined parameter-criterion, a conclusion is made about the state of the conductive coating in the region including zones I and II, where the measurements were made. Similar measurements and comparison with a predetermined parameter-criterion are carried out in other structurally unreliable sections 11 (figure 2) of the internal circuit of the tube electrode (anode). Such sections are the connections of the internal conductive coatings to each other using contact devices, as well as the contact point of the internal conductive coating of the cone with the external terminal of the picture tube anode.

 This method can be used to test both depressurized and evacuated and sealed devices, and can improve the effectiveness of control. The application of the method is possible in the production process of kinescopes for checking the integrity of the inner circuit of the anode of the tube shell before vacuum processing, as well as for checking individual parts, for example, the quality of the connection of the inner conductor coating of the cone with the anode output.

Sources of literature:
1. Japanese application 1157028, H 01 J 9/42, cl. G 01 R 31/24, publ. 06/20/89

 2. Iorish A. E. et al. Fundamentals of technology for the production of vacuum devices. L .: Energy, 1971., p. 267-268 (prototype).

Claims (1)

 A method for monitoring the internal electrical circuits of electrodes of an electrovacuum device with internal and external conductive surfaces, comprising applying to the external output of the internal electrode an alternating voltage of a given amplitude with a frequency F, obtaining control parameters using a measuring device and then analyzing them, characterized in that using an additional electrode placed on the outer surface of the device, free from conductive surfaces, and connected to the measuring device, determine the control parameters by sequentially placing an additional electrode in two adjacent zones in the area of the internal circuit of the controlled electrode of the device and analyze by comparing the difference between the obtained parameter values with a predetermined parameter-criterion, and the frequency F supplied to the external output of the internal electrode of the alternating voltage is selected from relation 2 / RC≥F≥1 / RC, where R is the structurally specified resistance value for the internal circuit of the electrode to be monitored, C is design su- predetermined value of capacitance between the inner conductor circuit controlled by the electrode and a conductive outer surface of the device.

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