SU1483384A1 - Rotating element of induction electric power meter - Google Patents

Abstract

The invention serves to improve the accuracy of induction meters of alternating current electrical energy. The rotating element consists of a branched magnetic circuit 1 with excitation winding 2 and a magnetic conductor with excitation winding 4. Negative feedback has been introduced into the parallel circuit, which consists of an AC voltage amplifier 5, a feedback winding 7 on the counterweight 6 and a voltage divider 8. This makes it possible to stabilize the parameters of the working magnetic flux of this circuit, which contributes substantially by a 30 ... 50% decrease in the energy measurement error. 1 il.

Description

The invention relates to electrical engineering, in particular to means for measuring electrical energy in alternating current circuits.

The aim of the invention is to improve the accuracy of induction meters for electrical energy of alternating current.

The drawing shows a block diagram of a rotating element of an induction counter.

The rotating element consists of a branched magnetic circuit 1 of a parallel circuit with a field winding 2 on the central shaft and a magnetic circuit 3 of a series circuit with a field winding 4. The field winding 4 is directly connected to the current circuit of the controlled load, and the field coil 2 is connected to the load voltage in series with the output of the AC voltage amplifier 5. The working magnetic flux of the parallel circuit Ф „is closed through the opposite pole 6 to the side rods of the magnetic circuit 1 (the bracket of the opposite pole, along which the working magnetic flux is closed, is not indicated). Directly on the flow path Ф „on the opposite pole 6 there is a feedback winding 7, connected by one output to the input of the AC voltage amplifier 5, and the second to the output of the resistive voltage divider 8, which is connected to the terminals of the power supply by its inputs. The feedback winding 7 is turned on in such a way that the signal at the input of the AC voltage amplifier 5 is determined by the difference in the EMF of the feedback winding 7 and part of the input voltage of the parallel circuit. The ratio of the resistance of the resistors of the voltage divider 8 and the number of turns of the feedback winding 7 are selected based on the specified ratio between the input voltage of the circuit and the working magnetic flux Ф „for the normal mode of operation of the counter.

The device operates as follows. During normal operation of the EMF counter, the feedback windings 7 and part of the input voltage taken from the resistive voltage divider 8 are equal to each other, are in antiphase, and therefore, the input and output voltages of the AC voltage amplifier 5 are equal to zero. In this case, the working magnetic flux of the parallel circuit has a predetermined value and is 90 ° behind the input voltage in phase, since the EMF of the feedback winding, in turn, also lags 90 ° from the flux Ф „. When changing operating conditions, for example, when changing the frequency, the magnetic flux parameters Phi and, accordingly, the EMF of the feedback winding 7 change. The voltage proportional to the difference signal of the resistive voltage divider 8 and the EMF of the feedback winding 7 appears at the output of the AC voltage amplifier 5, which leads to a change in the voltage across the excitation winding 2 and, accordingly, the module and phase of the magnetic flux Ф _and . With the indicated polarity of the connection of the feedback winding 7, the change in the flow parameters Ф _о and the EMF of the feedback winding 7 occurs in the direction of decreasing the input signal of the AC amplifier 5. With a sufficiently high gain of this amplifier, the phase shift between the input voltage of the circuit and the working magnetic flux Ф „is practically equal to 90 ° regardless of the losses in the field winding and the magnetic circuit. Since at a constant input voltage in the circuit, the EMF of the feedback winding 7 is constantly constant, comparable to this voltage, and the value of the specified EMF is in turn proportional to the frequency and magnetic flux, the frequency change of the flux modulus Ф „obeys the condition {Ф„ = sop5T Since the module the flux Ф „is determined by the parameters of the resistive voltage amplifier and feedback winding 7, any change in voltage at the input of the circuit leads to a proportional change in the magnetic flux Ф„. In this case, the phase relations between this stream and the input voltage still remain unchanged.

The introduction of negative feedback into the parallel circuit of the rotating element of the inductive counter makes it possible to stabilize the parameters of the working magnetic flux of this circuit, which contributes to a significant (approximately 30–50%) reduction in the error of energy measurement. In addition, the proposed design of the rotating element of the induction meter allows you to simplify the assembly and adjustment of the device. The automatic maintenance of the parameters of the working magnetic flux of the parallel circuit at a given level, regardless of the scattering fluxes and the parameters of the magnetic circuit material, allows the use of cheaper magnetic materials and the expansion of the technological tolerance zone in the manufacture of individual components of the structure, while the flux regulation „„ can be technically simply made by changing the resistances of the resistors, included in the comparator voltage.

Claims (1)

Claim A rotating element of an induction electric energy meter, containing a parallel magnetic circuit, consisting of a branched magnetic circuit with an excitation winding on the central rod and a pole, a serial magnetic circuit, on the magnetic circuit of which an excitation winding is arranged, which, in order to increase the accuracy, parallel circuit additionally contains an AC voltage amplifier, a resistive voltage divider, and a feedback winding placed on the pole, and the first output of the feedback winding is connected to the input of the AC voltage amplifier, its second output is connected to the output of the voltage divider, the first input of which is connected to the first terminal of the supply network, and its second input is connected to the second terminal of the supply network and the first terminal of the field winding of the parallel circuit, the second output of which is connected to the output of an AC voltage amplifier.