DE182075C - - Google Patents

Description

PATENT OFFICE.

PATENT LETTERING

-Ju 182075 CLASS 21 d. GROUP

Compensated machines usually require a small main field because of the armature feedback is canceled by the compensation winding. This fact constitutes a disadvantage in some cases, z. B. if the compensated motor as an elevator motor or train motor with possible should start with great tightening force. If the main field is low, it will of course be the same

ίο greater amperage required to start up ".

To achieve the spark-free running of the machine intended with the compensation As is well known, there must now be a compensation field in the direction of the working brushes which is the armature field generated by the working current in the direction of the brushes exceeds by a certain amount. The compensation winding can be used as a think in three parts. The first part, which is about the armature winding the effect is the same, serves to cancel the armature field, the second part removes the self-induction of the commutated DC current, the third part is used to generate a voltage that corresponds to the ohmic Voltage drop corresponds to the short-circuited coil. Of this is the first part the size respectively. Effect regardless of the number of revolutions and must also at standstill be present, the other two parts are not necessary when starting and must be all the more effective, the higher the The number of tours increases. ·

According to the invention, these latter two parts, i.e. H. the excess of the compensation field through the pure anchoring reaction in the direction of the working brushes during the tempering completely or partly used to strengthen the main field.

For this purpose, according to FIGS. 1 to 3 of the drawing, the compensation winding is made from several parts b \ b ' ² , the axes of which are adjusted with respect to the axis of the field winding λ. The winding direction and the position of the windings b ^l and b ' ² can now, as described in patents 162412, 172335 and 166902, so. be chosen that they deliver a field supporting the main field or not, depending on the winding parts b ^l , b ^{2 of} a switched off or switched on in parallel connection (Fig. 1 and 3) or in series connection (Fig. 2) and 2) or is switched (Fig. 3). -.

According to FIG. 1, when b ¹ starts up, a field is generated, one component of which falls in the direction of the brushes and the other component of which falls perpendicular thereto. The latter component reinforces the main field generated by α. After starting, b ^{2 is} switched on and now b ² and b ^l together generate a field, the direction of which essentially coincides with the direction of the brushes.

FIG. 2 differs from FIG. 1 only in that, in normal operation, & ^{2 is} in series with b ^x .

According to Fig. 3, a constant, the armature field always canceling compensation winding b can be present and by switching the part b ' ² only either, according to the position of the switch shown in Fig. 3, a field supporting the main field or in the other position of the Switch the additional compensation can be produced.

Fig. 4 shows the arrangement of the field winding α on the stator of a four-pole machine as an exemplary embodiment, namely half of the stator circumference is intended to be developed in a straight line. The arrows shown show the spatial distribution of the poles N and S.

5 and 6 show the arrangement of the compensation windings b ^l and b- and the poles produced by them for the case that b ^x is switched on alone (FIG. 5), that is, a field is generated which "is a component in the direction which supplies brushes and a component perpendicular thereto, or in the event that both windings b ¹ and b ' ^{2 are} switched on (FIG. 6) and generate a field, the direction of which essentially coincides with the brush axis.

FIG. 7 shows the case corresponding to FIG. 3, in which a compensation winding b which always cancels the armature field is constantly switched on. The poles produced by the winding b are indicated by dotted arrows. If, according to FIG. 7, the two winding parts b ¹ and b ^{2 are} switched on, they bring about the amplification of the main field generated by the field winding α , which is useful for start-up, if one of the two windings b 1, b ² , for example b ² , is switched over , these two windings provide a field falling into the brush axis according to FIG. 7, which field provides the additional compensation.

In FIGS. 1 to 3, the direction of the field produced by the winding parts b ^l , b ² in the axis of the main field for the starting circuit shown in the drawing is indicated by the characters -f- and ■ -. In Fig. 1, for. B. only the winding b ¹ supporting the main field is switched on, whereas the winding b ² , which is connected opposite the main field, is switched off. The winding b ^{l in} this case carries approximately twice the current as during the actual operating circuit when the switch is closed.

Of course, the compensation winding does not need to consist of two parts, one of which has to be switched off or switched, but can also consist of a single part, the magnetic axis of which can be adjusted with respect to the main field winding. During the start-up, the magnetic axis of the compensation winding is adjusted so far that only one component of the field generated by it falls in the direction of the working brushes and another component intensifies the main field with compounding. The adjustment of the magnetic axis is expediently done by changing the power supply point on the compensation winding. In Fig. 8, for example, it is shown in dotted lines how the connection points of the compensation winding must be adjusted with respect to the brushes in order to produce a compounding field component in the direction of the main field during tempering while reducing the compensating field component to that to cancel the simple one. Anchor field required dimension. The connection of the compensation winding b after it has started is drawn in solid lines in FIG. 8.

The circuit according to FIG. 2 can also be changed in such a way that when starting the main current flows through all coils in the same sense; after a successful start, however, either b ' ² or b ^{l is} switched over instead of switched off. '

The main winding α is in all of the go figures as a series winding. drawn, but it can also be in the shunt to the network or to the machine. Motors switched in this way can be used with great advantage as elevator motors and the like, in that they start up as compound motors with a high starting force and then maintain a constant number of revolutions.

In other cases, part of the winding α can be in the main stream and part in the shunt.

Claims (1)

Patent claim: Regulation of compensated DC and AC commutator motors, thereby characterized in that an excess of the compensation field required during normal operation when starting by switching parts of a multi-part compensation winding - or adjusting the axis of a one-part compensating ring winding is used to reinforce the main field. 1 sheet of drawings.