SU1272374A1 - Device for performing quality control of articles - Google Patents

Description

Four control groups consisting of two-level comparators have been installed. The number of comparators in each group is N + 1, where jsj is the number of types of defects controlled by MC. The level of operation of each comparator is determined by the interval of possible values of voltages at the outputs of amplitude 8 and 9 and frequency 6 and 7 analyzers, which correspond to a specific type of defect. The proposed device makes it possible to carry out complex control of the MK according to geometrical and technological parameters and with high accuracy to reveal simultaneously many types of defects controlled by MK: the overlap of the contact parts, their displacement relative to each other, the misalignment, the gap between the contact details, flask glass float and contact details coating condition. 2 hp ff, 3 ill.

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The invention is intended to control the quality of electronic products and can be used in the development, production and operation of sealed magnetic contacts (reed switches).

The purpose of the invention is to provide the possibility of controlling the quality of the sealed magnetically controlled contacts (reed switches), increasing the reliability of the control and expanding the operational capabilities of the device by enabling the simultaneous evaluation of the geometric and technological indicators of the reed switches.

Figure 1 shows the functional diagram of the proposed device for controlling the quality of reed switches; figure 2 - block diagram of the signal processing unit; FIG. 3 shows oscillograms of oscillations of the contact details of the test reed switch over one complete cycle during its periodic triggers.

The device (figure 1) contains a series-connected transducer 1 of mechanical and acoustic oscillations into electrical signals, amplifier 2, time selection unit 3, blocks 4 and 5 of band-pass filters, frequency analyzers 6 and 7 and amplitude analyzers 8 and 9, signal processing unit 10 , block 11 indicating types of defects and load sensor 12. As a transducer 1 of mechanical acoustic oscillations into electrical signals, a piezoelectric transducer is used, which is mechanically connected to the grounded output of the reed switch.

In the device, the first input of the time selection unit 3 is connected to the first input of the load sensor 12, the second input of the time selection unit 3 is connected to the output of the amplifier 2, the first output of the time selection unit 3 is connected to the input of the first filter unit 4, the second output of the time selection unit 3 is connected to the input of the second block of 5 filters, and the input

block 11 display types of marriage is connected to the output of block 10 signal processing. The test load sensor 12 is in the form of a current generator 13, a sample resistor 14, a detector 15, the first output of the test load sensor 12 is connected to the second output of the reed switch and the synchronization input of the time selection unit 3.

Figure 2 shows the block diagram of the signal processing unit 10, which includes four control groups of (Nf-1) two-level comparators 16 and (N + 1) four-input circuits And 17, where N is the number of controlled parameters of reed switches, each the input of each four-input circuit AND 17, corresponding to a certain controlled parameter, is connected to the output of one of the comparators 16 of each of the four control groups corresponding to the same defined

to the controlled parameter in this control group, the output of the four-input circuit I 17 is connected to the reject indicator corresponding to this controlled parameter in the block 11 of the display of the types of defects,

all the first control inputs of two-level comparators 16 are combined and connected to the output of load sensor 12, in each control group the second information inputs of two-level comparators 16 are combined, the information inputs of two-level comparators 16 of the first control group are connected to the output of the first frequency analyzer 6, the information inputs of the second two-level comparators the control groups are connected to the output of the second frequency analyzer 7, the information inputs of the two-level comparators of the third control group with unified with output of the first amplitude analyzer 8. The data inputs of the fourth group of two-level comparators are connected to the control output of the second amplitude analyzer 9.

In addition, the device (Fig. 1) contains an IG source of periodically varying electrical voltage and a control coil KU connected to its output, by means of which oscillations of the contact parts of the controlled reed switch are excited.

The test mode is chosen so that the reed switch works with a certain load, at which its contact parts collide and rub against each other with such efforts, at which mechanical and acoustic oscillations appear, allowing them to further determine the nature of defects by their further processing. (or lack thereof) in a controlled reed switch.

Fig. 3 shows almost removed oscillograms of oscillations of contact parts of a reed switch over one full cycle during periodic operations. On these oscillograms, TI is the time interval when the contact parts are in the open state, T2 is the time interval when the contact details are closed. As seen in FIG. 3, the frequency components for these two intervals are different. In addition, the nature of the contact part oscillations is different for reed switches of different quality, as can be seen from a comparison of the oscillograms a and b (Fig. 3), taken from two reed switches of the same type, but with different defects.

The device works as follows.

The current excited by the IG source in the KU coil generates a periodically varying magnetic field that acts on the contact details of the controlled reed switch MK, causing them to oscillate in a certain test mode. In this case, the contact parts collide and rub against each other with their working surfaces, and mechanical and acoustic vibrations occur in them, which propagate along the contact details, the outer ends of which are the conclusions of the reed switch. A piezoelectric sensor 1 mechanically connected to the output converts these oscillations into electrical signals, which are amplified by amplifier 2 and fed to a time selection unit 3. The latter allows you to choose from the total spectrum of signals coming from the piezoelectric converter signals of two characteristic time intervals - for open and closed states - contact parts.

From the output of the time selection block, the separated signals arrive at blocks 4 and 5 of bandpass filters, each of which has its own bandwidth. The signals passing through the filters are fed to frequency 6 and 7 and amplitude 8 and 9 analyzers. The output of the amplitude analyzers produces a constant voltage proportional to the average value of the signal in the passband of the corresponding band-pass filter, and the output of the frequency analyzers produces constant voltages proportional to the frequency of the spectral components with a maximum amplitude. At the same time, the characteristic features of the vibration spectra are recorded for both open and closed states of the controlled reed switch. The output signals of the amplitude and frequency analyzers are fed to the signal processing unit 10, at the input of which four control groups are set up, consisting of

0 two-level comparators 16. The number of comparators in each group (N + 1), where N is the number of types of rejects of controlled reed switches. The levels of operation of all comparators are individual and are determined by the intervals of possible voltage values at the outputs of the amplitude and frequency analyzers, respectively, of suitable reed switches and reed switches with certain types of defects.

For each specific defect of monitored monitored reed switches, their ratios of frequencies and amplitudes of the component frequency spectra in the open and closed state of the contact details are characteristic. Logical signals from the outputs of the comparators 16, which extract in their group the signals corresponding to a specific defect of the reed switch, are fed to the inputs of the circuits AND 17. If there is any circuit at all inputs AND levels of the logical unit, the output of this circuit produces a signal that goes to the indicator 11 types of marriage, which shows the type of marriage or lack of it in a controlled reed switch. The synchronization and stabilization of the operation of the device is carried out by means of a test load sensor 12, the outputs of which are connected to a time selection unit and a signal processing unit. In addition, the test load sensor 12 is designed to provide a current load for the reed switch. In principle, various reed switch tests can be carried out with both completely disconnected contacts (the so-called dry circuit mode) and current load mode. KOKs as a rule, tests in current load mode are more informative and give more accurate results to the actual operating mode of the reed switch. The required current load mode, determined by the specification for each type of reed switch, is provided by the current generator 13.

It is the presence of such a load that makes it possible to determine the state of the reed switch contacts (closed-open) and, therefore, to receive a signal to synchronize the operation of the device. The time selection unit receives signals about the moments of opening and closing of contact parts of the controlled reed switch from the test load sensor. These signals synchronize the operation of the time selection unit, which separates the oscillations of the reed switch into two characteristic sections TI and T2. The change in current load can lead to some change in the spectra of acoustic oscillations; therefore, it is necessary either to take measures to strictly stabilize the mode, or to introduce a correction into the operation of the signal processing unit. The correction of the signal processing unit is performed as follows. The impulse voltage from the reference resistor 14 is converted by the detector 15 into a constant voltage, carrying information about the magnitude of the test load and its correspondence to the specified value. This voltage is applied to the control inputs of all the comparators 16 of the signal processing unit 10. As a result, with random changes in the test load, the response levels of the comparators change in accordance with changes in the spectra of the acoustic oscillations of the reed switch.

Thus, the proposed device, designed to conduct a comprehensive control of reed switches according to geometrical characteristics and technological indicators, makes it possible to identify with high certainty many informative parameters that determine the quality characteristics and types of rejects of controlled reed switches. Using the proposed device, such quality characteristics of reed switches can be monitored, such as the amount of overlap of the contact parts, their displacement relative to each other, misalignment, the size of the gap between the contact parts, the presence of foreign particles in the reed switch, the influx of glass flask, the integrity of the flask details, etc. At the same time, the integral assessment of the quality of the reed switch significantly reduces the monitoring time (two to three times). The estimated economic efficiency of using the invention only in the production of reed switches is about 90,000 rubles. in year.

Claims (3)

1. A device for quality control of products containing a series-connected transducer of mechanical and acoustic oscillations into electrical signals, an amplifier, a filter unit, an analysis unit of a spectrum of signals, a signal processing unit and a load sensor, characterized in that in order to enable the quality control of the sealed magnetic control contacts (reed switches), increasing the reliability of monitoring and expanding the operational capabilities of the device by ensuring the possibility of assessment of geometrical and technological indicators of reed switches, a time selection block, a block of indication of types of defects and the excitation source of the control winding of the test reed switch were entered into the device, the first input of the time selection block is connected to the first output of the load sensor, the second time selection input is connected to the amplifier output, the first the output of the time selection unit is connected to the input of the first filter unit, the second output of the time selection unit is connected to the input of the second filter unit, the input of the display unit is It is connected to the output of the signal processing unit, with 0 analyzing the signal spectrum block being two-channel, the first channel of the analyzing signal spectrum block contains the first frequency analyzer and the first amplitude analyzer connected in parallel, the second channel of the analyzed signal spectrum block contains the second frequency analyzer and the second amplitude analyzer included also parallel. 2. The device according to claim 1, characterized in that the block of indication of the types of defects contains 0 reject indicators according to the number of monitored parameters N, and the signal processing block contains (N-bl) four-input And circuits and four control groups, each of which contains () two-level comparators, each input of each four-input And circuit corresponding to a certain controlled parameter is connected to the output of one of the comparators of each of the four control groups, corresponding to the same controlled parameter in this control group, the output of the four-input circuit I is connected to the corresponding controlled one I think that the reject indicator in the reject type indication block, all control inputs of the two-level comparators are combined and connected to the output of the load sensor, in each control group the information inputs of the two-level contactors are combined, the information inputs of the two-level comparators of the first group of control are connected to the output of the first frequency analyzer, information inputs two-level comparators of the second control group are connected to the output of the second frequency analyzer, the information inputs of the two-level controllers mparatorov third group are connected to a control output 5 of the first amplitude analyzer, the information inputs of the two-level comparators of the fourth group of controls are connected to the output of the second amplitude analyzer. 3. The device according to claim 1, characterized in that the load sensor is made in the form of a current generator, a detector and a load resistor, the detector input is connected to the output of the current generator, the detector output is connected to the input of the signal processing unit, the load resistor is connected in series the current generator and the terminals for connecting the test reed switch.