DE348799C - Induction counter with a two- or more-pronged main current drive core on one side and a three-pronged shunt drive core on the other side of the armature disk - Google Patents

Description

Induction meter with a two-pronged or multi-pronged main drive core on one side and a three-pronged shunt drive core on the other the armature disk. In the case of induction meters, as is well known, the effective shunt field must against. the effective main current field be delayed by go ° so that the meter provides correct information in the case of inductive loading.

In order to achieve this goal, one assigns a magnetic one to the main current core Shunt and lets secondary fields arise in this ineffective part, so you get a counter, its information on, the shape of the curve and the number of periods of the supplied alternating current are independent within, far greater limits than with Counters for those who go ° shift due to secondary fields in the effective part of the shunt field is generated.

So far, suggestions or explanations have been based on, counters, with a magnetic shunt in the main stream only on meters with a three-pronged drive core on its middle prongs the tension coil and on its outer legs. the main current coils were or vice versa. With such a structure there are none special precautionary measures to be taken into account.

However, if one uses counters with a two-pronged or multi-pronged Main current drive core on the other side of the armature disk is a three-pronged tension core opposed to this, the good functioning of the meter depends essentially on the correct one Arrangement of the shunt bracket. First of all, it is desirable to do this in this way to attach that through him a broadening of the cross-section for the river effective. Main stream lines brought about the damping by this Diminish field. Thorough experiments have now shown that it is absolutely necessary is to prevent with such an arrangement that at the same time the cross section for the flow of the effective shunt field is widened, otherwise in proportion between attenuation of the effective main current field to attenuation of the effective shunt field no change occurs which in itself has beneficial effect of widening the river thus does not appear from the main current field. This caution is particular then not to be disregarded when the self-consumption of the shunt coil is small is maintained, so the effective shunt field compared to the effective main current field is not significant in itself. Arrangements through which this goal is achieved, form the subject of the invention. If you take z. B. a. Induction counter on, at the, as shown in the drawing, a three-pronged tension drive core n a two-pronged current core h faces the other side of the armature, so let the magnetic shunt clip provided with adjustable short-circuit windings rl and -r2 b to the two poles of the main current drive core either at the yoke j of this core or; as indicated in the drawing, attach to the yoke il of the shunt drive core. The latter type of fastening will be preferred for the reasons given below. It now seems obvious to avoid an expansion that is too broad for the poles of the main current drive core h brought up Ends e of the bracket b to put on the inner sides of the main current poles, in such a way that through the Ends e the width of these poles is increased. But this would be flawed because due to the arrangement of the choke circuit d de: shunt core to the outer Legs of the same from the ends e of the bracket to the throttle cores k also effective The secondary force line would thus lead to a widening of the pole track the inference for the effective magnetic shunt force lines would lead. In the drawing, the inference of the shunt field is given by the bracket b1 causes thought that can consist of one piece with the bracket b. Instead of this Bracket b1 could also be a third one located in the middle of the main current drive core Kick the tines. It is therefore absolutely necessary with the arrangement shown, bring the ends e of the bracket b to the outer surfaces of the Hauptstromtriebkerres. If you really wanted to place the temple ends e on the inner sides of the main current poles, so the throttle gap d would have to be attached to the middle leg of the shunt iron embarrassed. If you want to use the short-circuit rings y arranged on the bracket b, and r, not just the go 'shift, but also due to its asymmetrical position compensate the friction at the same time, so must be shown in the drawing Arrangement of the yoke j1 of the shunt core with the yoke j of the main current drive core be magnetically connected, for example by the support frame of the drive cores.

If the bracket b is not on the yoke of the Hauptstromkerres, but on the yoke attached to the shunt core, an arrangement which is not only desirable to get out of the area of the connection lines to the main current coils., but, which must also be preferred, in order for the short-circuit turns r1 and y, one as possible To obtain a long adjustment path, the bracket and short-circuit rings must be proportionate large cross-sections are obtained so that the required shift of go ° between the effective instinctual fields is achieved. If you lay. Value on a pleasing appearance and on the handiness of the regulating devices, so one can- without having to rely on the preference the independence in the meter information in the case of curve shapes deviating from the sinusoidal shape and having to do without fluctuating number of periods, the shift of go ° without too much mass accumulation in bracket b by also adding the effective shunt field by additional means beyond those by the inductive. Structure of the same given angle also shifts backwards, for example through the yoke b1, which smelled a short-circuit ring v, can wear, or only by applying a short-circuit ring to the middle ciliac of the shunt drive core, outside the throttle delimited by the core pieces k, or in some other way. It is only necessary for that. to ensure that this additional displacement angle remains small in relation to the displacement angle caused by the magnetic. Shunt to the effective main current field is generated.

Claims (3)

PATENT CLAIMS: i. Induction meter with a two-pronged or multi-pronged main current drive core on one side and a three-pronged shunt drive core on the other side of the armature disk, characterized in that on the yoke of the main current drive core or a point of the same magnetic potential, a magnetic bow (b) is shunted to the poles of the main current drive core (b) is arranged such that the path of the lines of force of the main current field passing through the armature disk is widened by the same, but not the pole track of the voltage flow. 2. Induction meter according to claim i, characterized by such a dimensioning and arrangement of the .effective parts that to achieve the required go 'shift not only the effective main current field through the. magnetic shunt to this compared to the consumption stream accelerated in time, but at the same time the effective Shunt field due to secondary fields induced by the shunt current is delayed in time with respect to the service voltage, in such a ratio. that the phase delay angle is much smaller than the phase acceleration angle is. 3. Induction meter according to claim i and 2, characterized in that the magnetic shunt bracket (b) has three legs, the middle of which the The end of the effective shunt lines of force forms, while the two outer ones the ineffective lines of force of the main current field lead. Induction meter according to claim and 2, characterized in that instead of the middle bracket leg of the execution according to claim 3, a third, between the two legs of the main current drive core lying prongs is provided, which forms a whole with the current cores.