DE696926C - Regulating reactor - Google Patents

Description

Control choke coil If you want control chokes with changeable If the air gap works with a relatively small air gap, this results in choke coils with a plunger core arrangement at the beginning of the path on short stretches of the plunger core large changes in the inductor's self-induction values. When using threaded spindles The largest part of the control range is therefore usually with a rectangular thread moved together on the first spindle revolution. If you want to get through this evil Encounter the use of fine threads, one must take into account that with immersion cores of up to now the entire magnetic pull of the Plunger core must be taken up by the spindle. This burden leads to rapid wear of the fine-The invention provides a reactor structure at which avoids the disadvantages of the previously known construction described above will. According to the invention, a throttle of normal design is at a certain angle to the axis of the moving member augeorder, so that the parallel to the poles of the Core lying yoke piece can be moved parallel to this axis. To the cancel tensile forces acting on the yoke perpendicular to the direction of movement, throttle cores are also advantageous zti both sides of the movable wedge-shaped yoke arranged.

A similar control system is already known, the but built in a rotationally symmetrical manner in the manner of the known induction motors is and its regulation by axial displacement, d.li. perpendicular to Sheet metal layering, of the rotor inside the stator core is accomplished. Such a one Arrangement is not only fundamental in its structure compared to the subject of the invention Differences on; exist in both magnetic and electrical drawing also disadvantages. As a result, 'the runner is displaced perpendicular to the sheet metal layering field distortions occur at the edges, additional iron losses as well Controller hum. Furthermore, the effective cross-section changes according to the axial Shift. The axial forces that occur must also be particularly absorbed will.

In Fig. I is an inventive embodiment of a three-phase throttle specified. The three-legged core i and its movable yoke piece 2 are opposite the movement spindle 13 inclined at a more or less large acute angle arranged. The spindle is mounted in a bracket .4, which is also used as Base plate for the choke core i is used. By means of the spindle 3, the yoke piece 2 can be moved in the direction of the spindle axis. With the assumed inclination of the yoke and the throttle to the spindle axis will move when the yoke is moved in the axial direction of the spindle a larger or smaller air gap between adjust the yoke 2 and the core i. Depending on the size of the angle of inclination between The throttle and the drive axle bring about an equal displacement of the yoke piece a larger or smaller air gap change.

The yoke piece 2 is attached to the yoke beams 5 and 6, which in turn by the shafts lying parallel to the drive spindle; and 3 are performed. With this arrangement, the largest component of the pulling force of the choke coils is based on transfer the yoke from the yoke beams 5 and 6 to the guide shafts 7 and 8, while only a small component is effective in the longitudinal direction of the spindle.

In the arrangement described above, the coils 9 and the Core i arranged on one side to the movable yoke piece. The guide waves 7 and 8 are therefore heavily loaded with the tensile force on the yoke piece.

In Fig. Ä, another arrangement is shown in which the guide shafts are relieved as much as possible. For this purpose, the core and coil sets are doubled and arranged on both sides of the movable yoke piece. The two iron circles i and ii are again arranged at a certain angle of inclination to the direction of movement of the drive spindle 12 and attached to the common threaded frame 13. The yoke of both choke coil cores is designed as a common wedge-shaped laminated core, but can also consist of two individual yokes assembled to form a rigid body, between which the drive spindle is similar to that in A66. i is passed through. The windings 1 5 of the throttle are now arranged in half size on both sides i of the yoke 14.

The movement of the yoke 1.4 takes place with the aid of the spindle 12 and the Handwheel 16. This movement creates an equal on both sides of the yoke large air gap, so that the forces acting on the yoke piece are mutually exclusive cancel and only the small component in the axial direction of the movement remains.

The coils belonging to a phase can be in series or as required can be connected in parallel. If the reactor is required in a six-phase system, so the six coils are conveniently placed in each phase.

Claims (3)

PATENT ANS P 1t ü c H r: i. Regulating choke coil with a constantly changing air gap and an iron core like a shell or core transformer, characterized in that a choke of normal design is arranged at an acute angle to the axis of the moving member and the yoke piece lying parallel to the poles of the core is displaced parallel to this axis can be. 2. Choke coil after Claim i, characterized in that two throttle cores on both sides of the movable wedge-shaped yoke are inclined and arranged so that the on the yoke Cancel tensile forces acting perpendicular to the direction of movement. 3. Choke coil according to claim 2, characterized in that two normal straight yoke pieces to one solid whole in a wedge shape so connected that they come together in the axial direction of the moving member shifted.