SU1051438A1 - Shunt for measuring pulse current - Google Patents

Description

1 The invention relates to electrical measuring equipment and is intended for use in the study of pulsed currents with short (less than a few microseconds of the front in conditions when the parasitic inductance of the shunt is created preconditions for the endowment of the signal removed from it with a systematic error proportional to the current rise rate. A shunt is known for measuring pulsed currents, made in the form of a conductive loop with a shape and size determined by the operating range of the measured current. A disadvantage of the known This is due to the incomplete exclusion of parasitic inductance and, as a result, with a low measurement accuracy, the closest technical solution to the proposed is a shunt for measuring pulse currents, containing two parallel branches, each of which is one of two consecutively, but different order of included current-carrying conductors with the same inductive and significantly different resistances, In the device, with equal inductances of the current-carrying conductors, the parasitic component The signal turns out to be compensated for zj. However, the disadvantage of this design lies in the considerable complexity of manufacturing and tuning, since in practical implementation of the known shunt it is necessary to ensure very accurate equality of currents in both parallel branches and inductances of different types of conductors, in particular copper and nichrome. Another disadvantage of the device is that none of the bridge terminals can be at zero potential. This circumstance significantly limits the scope of application of the known shunt. The purpose of the invention is to simplify the manufacturing and adjustment of such a device. This goal is achieved by the fact that in a shunt for measuring pulsed currents containing two current-carrying conductors connected in series between the input terminals of the device with various 82 ratios of active and inductive resistances, an adjustable resistive voltage divider is connected in parallel to the said set of conductors, and one of the output the terminals of the device are combined with one of the input terminals and grounded, and the other two output terminals are located at the junction of the current-carrying conductors and arms elitel voltage. In order to match this shunt with the wave, the resistance of the measuring path, coax, and the constant voltage resistor is chosen to be equal to this impedance, the additional terminating resistor is connected to the connection point of the current-carrying conductors and the corresponding output terminal of the device. FIG. An electrical circuit of the proposed shunt is provided for measuring pulsed currents; in Fig.2 a, 6 waveforms of the output signals of the shunt before and after its setting; Fig. 3 shows a replacement circuit for calculating the mode of compensation for the tokensui inductances | of their conductors in a particular case of a shunt implementation. The device consists of two parallel branches connected to the input terminals 1 and 2 (c1) ig.1). One of the branches / low-resistance V contains successively connected, current-carrying conductors 3 and A. The other branch (potential, high-resistance) is an adjustable voltage divider consisting of a series-connected constant 5 and adjustable (trimming) 6 resistors. One of the output terminals 7 of the device is combined with the input terminal 1 and is grounded, and the other output terminals 8 9 are located at the junctions of the current-carrying conductors 3 and the arms S, b divider voltage 1 (Eni. If the shunt needs to be matched with the wave resistance of the measuring path the resistance of the resistor 5 is chosen to be equal to: this impedance, and between the junction of the conductors 3, and the output terminal 9 includes an additional terminating resistor 10. The process of measuring the shunt current with a shunt is carried out When a pulse signal is applied to input terminals 1 and 2 with a steep front from a generator of calibrated signals, voltage I between output terminals 8 and 9, due to the presence of uncompensated inductances in the current-carrying conductors 3 and C, will have a form with pronounced spikes Fig. 2 a), With the help of an adjustable resistor 6, the parasitic signals are compensated for by the inductances of the conductors 3 and 4, which is monitored by the disappearance of the emissions on the oscillogram of the output signal (J of the shunt of Fig. 2cH). After the shunt is tuned, the measured voltage of the shunt is calculated from the measured resistances of the arms 5.6 of the voltage divider and conductors 3. Following this, the adjustable resistor 6 can be replaced by an equivalent constant resistor. The following calculation, carried out for the particular case depicted in the Gfig.3 replacement circuit, illustrates the principle of inductance compensation in the proposed shunt. The signal on the display of the axis of the plots with the Differential input corresponds to U - U, -U2, U, 3rD42bi |. S.4. (Delivered (l) and (2) to (G), we get 3k-4 2k-3, dO I - 3 --- g +; I,. K. Di. It is easy to see that the compensation of the signal components, associated with the inductance of the current-carrying conductors 3 and will be possible with the voltage dividing factor K 3/2. Then the signal from the shunt will only have an active component proportional to the measured current 3 l / 33-r the presence of an adjustable resistor 6. Thus, it is much easier to manufacture and adjust the proposed shunt than known bridge, requiring careful selection of its resistors to ensure the same accuracy.This tuning method can be applied to eliminate the parasitic signal component during measurement and other parameters.The presence of a grounded terminal in the shunt design provides better security.

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FIG. 2

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Claims (2)

1. A SHUNT FOR PULSE CURRENT MEASUREMENTS, containing two current-carrying conductors connected in series between the input terminals with different ratios of active and inductive resistances, and is grounded, and two other output terminals are located at the junction of the current-carrying conductors and the voltage divider arms. 2. Shunt pop. 1, distinguishing with the fact that, in order to match it with the wave impedance of the measuring path, the resistance of the constant resistor of the voltage divider is chosen equal to this wave impedance, and between the junction of the current-carrying conductors and the corresponding output terminal of the device an additional terminating resistor. (L s