DE343813C - - Google Patents

Description

Blind consumption meter based on the induction principle. With a blind consumption meter according to the principle of induction, as is well known, the voltage drive field must match the main current drive field be in phase when the main current is in phase with the voltage. About this phase equality to achieve the two drive fields, according to the invention, the voltage circuit of the The device is constructed as follows .. The voltage drive magnet is a choke coil connected in parallel, the time constant of which is higher than the time constant of the drive magnet. Both together are preceded by an induction-free or weakly inductive resistor. The time constant of the branch of the parallel connection with the voltage drive magnet by switching on an induction-free or weakly inductive resistance against the time constant of the branch with the choke coil can be pressed down.

Fig. I of the drawing shows the circuit diagram of one according to the invention built-up voltage circuit; Fig.2 the associated vector diagram. The Fig. 3 is the circuit diagram of a reactive consumption meter for three-phase current with Aron circuit of the two measuring systems.

In Fig. Z i is the winding, 2 the core of the voltage driving magnet. The drive pulley 4 protrudes into its air gap 3, 5 is the winding, 6 is the core of the Choke coil; the core is composed, for example, of two parts and contains two narrow air gaps 7. The windings i, 5 is an induction-free resistor 8 upstream. 9 and io are the power lines, of which the whole voltage circuit is branched off.

In the vector diagram, e is the voltage between the branch points of windings i and 5; it is the voltage at the series resistor 8; E is the voltage between the power lines 9 and io; N is the voltage drive field. i, i5, i8 are the currents in the windings i and 5 and in the series resistor B. il lags behind e by the angle cpl, and N lags behind i by the angle ip. i, lags behind e by an angle 95 which, because of the higher time constant of the choke coil, is greater than the angle qpl and, if the dimensions of the choke coil are chosen correctly, can be brought close to 90 °. i3 is the resultant of i, _ and i. At the tip of e, e8 is plotted parallel to i $. The length of e $ is proportional to the ohm number of resistor B. E is the resultant of e and es.

The diagram shows that by changing e $ the voltage E can be brought to phase equality with N, yes even to lag behind N. The phase equality of E and N assumed for the diagram is required, if - the main stream drive field is in phase with the main stream. The main power drive field rushes after the main flow, N must lag behind E by the same amount.

It can be seen from the diagram that from the voltage E one um the greater part is attributable to the tension e, which is responsible for the strength of the tension drive field N is decisive, the greater q) 5 is. It follows from this that it is useful to use the time constant the choke coil should be selected as high as possible. In the same sense it works favorably if the required lag of E against e is reduced by artificial Increase in the angle by which the main current drive field can be achieved by known means lags against the main stream.

Claims (1)

Claim: reactive consumption meter according to the induction principle, characterized in that the voltage drive magnet is connected in parallel with a choke coil whose time constant is higher than the time constant of the voltage drive magnet and an inductive or weakly inductive resistor is connected upstream of both.