SU101888A1 - Method for separate balancing of ac bridges - Google Patents

Description

The subject of the invention is a method of separately balancing AC bridges produced in two operations, the first of which is to bring the two voltage vectors to perpendicularity, and the second to determine the absence of voltage on the bridge diagonal.

Already known methods are separate balancing of ac power lines, in which balancing is limited to two adjustments and there is no need to carry out repeated change of control of the two settings.

However, in the known methods, the determination of the moment of perpendicularity of two vectors, which together form some fixed voltage perpendicular to the power supply of the bridge, is made difficult by the absence of satisfactory operating phase indicators.

A distinctive feature of the proposed method is that the operation of reducing these two vectors to a mutual perpendicular pattern is performed by modulating one of them with a frequency f2 different from the feed frequency of the bridge fi. The second voltage vector is also modulated in amplitude, and when these two vectors, which form the same sum, are in quadrature, they are not, but the modulated oscillation will not contain the harmonic component of the frequency fa.

The drawing shows the principle scheme of the bridge, balanced by the proposed method.

The intermixed current bridge (1) consists of active resistances and capacitors. Unknown resistances are included between the point (2) and (3) of the bridge: resistance (4) and capacitor (5). Between the points (3) and (6) of the bridge, the capacitor (7) and the graduated variable active resistance (8) are included. The remaining two bridges (6) - (9) and (2) - (9) include active resistances: a constant resistance (10) and a graduated variable resistance (11).

The AC bridge is powered by a transformer (12), the secondary winding of which is divided into three sections (13), (14) and (15). The number of turns of the section (13) is equal to the number of turns of the section (14). Between the terminals (16) and (17) of the secondary winding are included: active resistance (18) and capacitor (19), proportioned so that the voltage between points (9) and (20) is 90 ° out of phase with respect to the voltage wedges supplied to the diagonal (3) - (9) of the bridge. In addition, the number of turns of section (15) is proportioned in such a way that the voltage modulus between points (9) and (20) is equal to the voltage modulus between points (3) and (9), multiplied by a constant coefficient equal to a fraction, the numerator which is equal to the magnitude of the active resistance (10), and the denominator - the reactive response of the capacitor (7).

The first operation of balancing the bridge is to bring the two voltage vectors to mutual mutual identification: the search between points (2) and (9) and the length of the curve between points (2) and (20). This operation is carried out with the aid of a change in matching (11).

The resistance (11) is included at the cathode follower path, condition, k1; it is not the electron tube (21) and is connected (22), connected to the cathode circuit. The voltage DI taken from the output of the cathode repeater is applied to a voltage divider consisting of a constant resistance (23) and resistance (24), the magnitude of which periodically changes according to such a law that the alternating voltage 2 at the terminals is countercurrent (23) It turns out to be a modulated frequency of 12, which is excellent at the frequency of the bridge's imitation. Since the average value of the voltage at the terminals of resistance (23) (points 9 and 25) is less in modulus at the terminals of resistance (11) (point 2 and 9), although it coincides with it in phase, instead of the terminals at terminals (2) and (20) during the measurement use the voltage at the terminals (25) and (26), proportioned so that the modulus of this voltage is reduced compared to the module iair) penny at the terminals (2) and (20) in in the same proportion, in the curtain the average value of the voltage module at the sop clips is reduced (23) but compared to the voltage at the sop clips motivation (11). RTAPr clips (25) and (26) coincide in phase with voltage at terminals (2) and (20).

Lrp of the mutual neuronicity of two vectors (voltage at clamps (2) and (9) and at clamps (2) and (20)) oscillations of the modulus napr; sn at clamps (25) and (26) are performed with a frequency of 2 f2 , and in the envelope of this modular voltage amplitude there is no component with frequency fa.

By applying voltage from zachlmov (25) and to the input of the rectifier (27), filtering, extracting, frequencies above the frequency fa by means of the filter (28), and with zero readings of the indicator (29), one can find the mutual perpendicularity of two vectors) tension

The subject is invented and

A method of separately balancing AC bridges, the first of which is the operation of bringing two voltage vectors, which in total form some kind of external power, a hyper-voltage iitany, and a mutual perpendicularity By the fact that, in order to detect deviations from the perpendicularity of these vectors, one of them is modulated in amplitude with a frequency fg different from the frequency tl and tI of the bridge, as a result of which the second vector also turns out to be modulated in amplitude than in mutual orthogonal vectors RIOST envelope modulated waveform corresponding to the second vector will not contain the harmonic component frequency fa.