DE378547C - Three-phase rotor winding - Google Patents

Description

Three-phase rotor winding. In the main patent 378546 is a starting circuit described for asynchronous motors, by means of which it is possible without starting resistance to get a large starting torque. It consists in that the rotor winding each Phase is broken down into individual winding parts, which overlap when starting Circuits are connected so that groups of interconnected and Winding parts of a phase that cancel each other out magnetically are ohmic Form resistance for the winding parts of the other phase.

Fig. 2 of the main patent shows a rotor winding in which the starting current of the motor is only ¼ of the starting current with normal working switching. According to the invention, the ohmic resistance of the closed circuits should now Rotor winding can be enlarged compared to the main patent. This is done through the circuit shown. As can be seen, each phase is in this schematic The rotor winding is also divided into two halves, namely the first one Phase from windings I and I ', the second from windings 2 and 2' and the third phase from 3 and 3 '.

The phase halves I, 2 and 3 are connected in star as in the main patent, but the ends of the remaining half-phases I ', 2' and 3 'are not to the corresponding ones Midpoints of half phases 2-3 and I connected, but to the midpoints A-B-C of half phases 2'-3 'and I'. In this way, the following three overlapping, obtained closed circles, namely I. I-A 'A-3'-3, II. 2-B' B-I'-I, III. 3-C ' C-2'-2. In each of these circles there is now a resulting E.M.K. Quarter of the E.M.K. that is induced in the whole phase. E.g. will in the rotor circle I the E.M.K., which is induced in the half phase I, by the E. M. K. of quarter phase A 'A canceled halfway; those in the remaining half phases 3'-3 induced E.M. Ke. are directed against each other and therefore raise each other on.

The current i, which is determined by the difference in the E. M. Ke. of the winding parts i and A A 'is caused, flows through the winding parts 3' and 3 as well as I and A A 'in the opposite direction, which is why the winding parts 3'-3 in magnetic Execution almost completely cancel if the corresponding conductor of the windings 3'-3 lie in common grooves, the winding parts i-A A 'compensate for Half.

The same applies to the other circuits II and III.

One moves the connection points A-B-C in one way or the other Direction along the half-phases I'-2'-3 ', so one can choose a larger or a smaller one Adjust starting current. If z. B. the connection points A-B-C to the points A'-B'-C ' are approximated, the value of the resulting E.M. Ke., which is in the three closed circles of the rotor winding act, magnifying what again one Causes an increase in the starting current. On the other hand, you can of course use the starting current of the motor by removing the connection points A-B-C from points A'-B'-C ' removed.

When transitioning to the running circuit, you can see the individual parts of the Short-circuit half-phases in stages; so you can z. B. with increasing speed of the motor first short-circuit points A-B-C and then points A'-B'-C '.

For motors where the current surges when starting are proportionate are small, you can be content with short-circuiting only the winding points A'-B'-C '.

Instead of the half-phases I'-2'-3 'one can, as in Fig. 3 of the main patent, short-circuit the half-phases I-2-3 in stages.

Claims (2)

PATENT CLAIMS: i. Three-phase rotor winding according to patent 378546, characterized in that the ends of the outer phase parts are connected to inner points (BCA) of the same winding parts of the adjacent phase parts (2'-3'-i '). 2. rotor winding according to claim i, characterized in that that the phase parts (i'-2'-3 'or i-2-3) are short-circuited in stages.