SU551576A1 - Device for monitoring pulse parameters of magnetic cores - Google Patents

Description

(54) DEVICE FOR THE CONTROL OF PULSE PARAMETERS OF MAGNETIC CORES 2. However, they have insufficient accuracy of control. The purpose of the invention is to improve the accuracy of control of cores. This is achieved by the fact that a device containing a series-connected current pulse generator, a magnetic unit and an amplifier whose output is connected to the inputs W of gated transducers, the second inputs of which are connected to the outputs of the strobe pulse generator connected to the Second output of the pulse generator current as well as the measuring unit equipped with an absolute granid control unit forming control unit, a control unit whose input is connected to the third output of the current pulse generator, and the outputs to the third inputs of gated direct generators, and comparison channels by the number of monitored parameters, their outputs connected to the inputs of the measuring unit; each of the comparison channels is made as a series-connected switch and comparison element, the second input of which is connected to the output of the gated converter, the output — to the input of the measuring unit, One input of the switch is connected to the output of the absolute control block forming unit, and the other to the output of the preceding gated converter. The drawing shows a block diagram of the device. The device contains a current pulse generator 1, which has a main output for issuing a test program and two additional signals for issuing clock signals and start signals that determine the origin of the delay of the strobe pulses, a multichannel generator of 2 strobe pulses with independent adjustment of the delay of the strobe pulses in each channel, programmable control unit 3 forming permissive pulses through conversion channels, magnetic unit 4 with contact device and measuring needle, measuring amplifier 5 s A set of strobe converters 6 with adjustable conversion factor K, forming N conversion channels, a set of M comparison channels 7, each of which in turn has a programmable switch 8 and a comparison element 9, an absolute boundary control unit 10 and a measuring unit 11, consisting of a grouping unit 12, units 13, averaging control results and AND elements 14 and 15. The outputs of the AND elements 15 are the outputs of the device. The device operates as follows. The test program of current pulses, formed at the main output of generator 1, is fed to the input of unit 4, which has a contact device with a measuring needle (probe), and carries out the magnetization reversal of the core. The signals read from the tested core are amplified by the amplifier 5 and fed to the signal inputs of the transducers 6, each of which operates in a certain tact of the test program. The work cycle is selected by block 3, which generates the necessary enabling pulses for each conversion channel. Synchronously with the starting pulses from the output of the generator 1, the generator 2 is started, which generates at the output of each of its channels strobe pulses with an adjustable delay relative to the start of the current reading pulses of the test program, which can be connected to the gates of the conversion channels. The transducers 6 of the k-channel from the t-conversion channels carry out the conversion of instantaneous values read from the tested core of signals or their amplitude (in case of strobe pulses) into secondary information (direct current, voltage, digital code, etc.) convenient for further processing. The quantitative value of information at the input and output of the 1st channel of the transformation is related by the ratio V4, K. . -. .... LYH n-VLX - quantitative values of the converted value at the input of the i-th channel converter; Y -gy; (- quantitative value of information at the output of the j-th channel converter; K "is the conversion factor of the i-th channel. Information from the outputs of the conversion channels, as well as information from the output of the unit Yu, corresponding to the absolute limits of the control parameters, goes to the channels 7. The number of the last M channels is determined by the required number of simultaneously monitored parameters and may lie within (N.KXN.KH), 2, where K is the number of simultaneously existing absolute limits of control, with one (working) input each a comparing element 9 comes directly from one of the transform channels, and the second (reference) input

4epets switch 8 is a signal received either from the absolute control bounding unit or from one of the conversion channels preceding the one connected to the working input. Depending on the ratio of the magnitudes of the signals at the inputs, the output signal of the reference channel may take a zero or one value. It is easy to see that in the case of supplying a reference from the reference control unit with absolute control limits in the comparison channel, the absolute level of the signal arriving at the working input is monitored, and in the case of applying a signal from another conversion channel to the reference input, incoming to the corresponding conversion channels, the ratio limit value being determined by the ratio of the conversion factors of these channels. Indeed, if the working channel is the i-th, and the specific j-th, then taking into account the relation (1 the boundary state of the comparison circuit is written in the following form. Ch, Ch, or Since all the conversion channels have adjustable coefficients The value of the ratio can be set to the required limits. In each comparison channel, the functions correspond to the one-way control of a parameter, i.e., the control by the upper or lower limit of the absolute value of the signal or the ratio of two signals. There are two conversion channels required for absolute values, and two for control of relationships. If two-way control is required, i.e., control over the upper and lower bounds, then in the first of these cases, one conversion channel and two comparison channels are needed, and in the second Three conversion channels and two comparison channels. The presence in the device of the ability to control the instantaneous values of the signals allows the control of the waveform, which is necessary in practice, to be carried out regardless of their amplitude. In particular, it is possible to control one of the main parameters of the cores, the magnetization reversal time tg, which is usually estimated at the level O, 1 of the amplitude of the signal of the intact unit and V, on the descending branch of the read signal. For two-way control of this parameter, three channels are transformed according to this V, which is ensured by supplying the corresponding pulse from block 3; By two

Strobe pulses with a delay time and corresponding to the upper and lower limits of the time tg are supplied from the channels, and the third channel operates without gating. The output signals from the latter are fed to the reference inputs of the two comparison channels; the output inputs of these channels are supplied with the output signals of the first two converters, and the ratio of the conversion coefficient of each gated channel to the conversion ratio of the non-gated channel is set to 0.1,

Claims (2)

For the purpose of grading the cores into several groups according to any of the parameters, (P + 1) comparison channels are used, where P is the number of groups, and a special group forming unit 12, which is part of the measuring unit whose inputs are output signals from the above channels of comparison. In this case, the decryption of input signals, giving a signal on one of its outputs that the core belongs to one of the groups. In order to reduce the effect of random errors made in single measurements, each parameter is monitored many times, followed by averaging the results obtained using blocks 13. The latter control the ratio of the number of measurements with a positive result to the total number of measurements and output the signals shelf life, if the specified ratio is greater than or equal to some predetermined value. The signals from the outputs of averaging devices for each of the monitored parameters, except for the group-forming ones, are sent to the I14 element, which outputs at the output a permitting signal that carries information about the overall fitness of the core according to these parameters. This signal is fed to the inputs of elements And 15, the second inputs of which receive signals from the outputs of averaging devices in groups. Thus, information on the belonging of the core to one of the groups is entered at the output of the device only if the core is suitable for all other parameters. By changing the number of comparison channels within the limits defined by expression (2), the functions of the switches can be simplified. If the number of channels is maximum, the need for switches is eliminated altogether. 7 claims 1. A device for monitoring pulsed parameters of magnetic cores, comprising a series-connected current pulse generator, a magnetic unit and an amplifier, the output of which is connected to the inputs ст of gated transducers, the second inputs of which are connected to the outputs of the strobe pulse generator connected to the second output of the pulse generator current, as well as the measuring unit, is different from the fact that, in order to increase the accuracy of the control, it is equipped with a block for the formation of absolute control limits, a block control, whose input is connected to the third output current of the pulse generator, and the outputs - to the inputs of a third gated converters and comparing the M channels for the number of controllable parameters, their 55 6 outputs connected to the inputs of the measuring unit. 2, the device according to claim 1, wherein each of the comparison channels is made up of a series-connected switch and a comparison element, the second input of which is connected to the output of the gated converter, the output is to the input of the measuring unit, one input commutator is connected with the output of the unit forming the absolute limits of the control, and the other with the output of the preceding gated converter. Sources of information taken into account in the examination: 1. Automatic device U-707, technical specification PS 2, 777,006 THAT. 2. Automatic control of magnetic parameters, Higher School, M., 1971. pp. 76-789 - (prototype).