DE897602C - Contact converter - Google Patents

Description

Contact converter The invention relates primarily to contact converters for high voltage power current. It is known, periodically moving contact devices to be arranged in a closed housing with a medium of higher dielectric strength can be filled as air, e.g. B. with an insulating gas or with air under increased pressure. Other known proposals boil down to a casing Create a vacuum or fill it with an insulating liquid. According to the invention a particularly advantageous arrangement can be achieved in that a number contact points connected in series and equipped with lifting contacts in a substantially cylindrical bowl in rows parallel to the bowl axis lie in a star shape around a drive shaft arranged coaxially in the boiler are grouped around. This allows while maintaining the required voltage clearances a good use of space and easy accessibility of the individual parts can be achieved, This also facilitates the monitoring and the repair or replacement damaged or worn parts is simplified.

The invention will be explained in more detail with reference to the drawing.

Figures r and 2 show a three-pole converter in cross-section, viewed from the side and from above; 3 contains individual parts in an enlarged view; Fig. Q. shows a three-pole circuit diagram, and in FIGS. 5 and 6, a six- or twelve-phase converter is shown in section, viewed from the side and in part from above. A basic component of the contact converter according to FIGS. I and 2 is formed by six contact blocks io, each of which contains a number of stationary contacts ii and movable contacts i2. The contact points are arranged in rows vertically below one another. In FIG. 3, some contacts are shown on an enlarged scale, seen in the closing direction. The stationary contact pieces ii are fastened at their ends on a frame plate of the contact block io with two fitting bolts each. One end is forked, so that only the bolt at the other end needs to be completely removed to replace a stationary contact piece. The movable contact pieces 13 each bridge two adjacent stationary contact pieces ii and therefore have no connections for the main current. They are designed with the smallest possible mass and are moved in groups by common force transmission members in a known manner radially outward so that they stand out from the stationary contacts perpendicular to the contact surfaces. As power transmission organs, for example, multiple plungers 13, the z. B. like hands are formed with fingers and are preferably made of insulating material at the ends of the fingers. When the plungers 13 go back again, the contacts are closed by powerful coil springs 14. The periodic movement of the plunger 13 is controlled by eccentric drive members 15, e.g. B. eccentrics, cams or cranks, which are located on a drive shaft 16. The drive shaft belongs to a synchronous motor 17 or is coupled to it. It is coaxially surrounded by a tubular body 18, at the upper end of which the motor 17 is mounted with a stator that can be rotated, in particular for the purpose of voltage regulation. The contact blocks are firmly connected to the pipe jacket. Two contact blocks each, which can be connected either in parallel or in series, belong to one phase of the three-phase system. The phases are spatially offset from one another by i2o °. The tubular body 18 hangs on the lid i9 of a boiler 2o, which surrounds the entire contact device. The motor 17 is enclosed by a special dome 21 so that it can be made easily accessible by removing the dome, without the boiler cover 19 having to be opened. At the lower end of the tubular body 18 there is a special space which is separated from the rest of the interior of the boiler by partition walls 22 and into which the free end of the drive shaft 16 protrudes. On the latter sits the movable part of an auxiliary switching device 23. This consists of two resting electrodes attached to bushing insulators 24 for each phase and a revolving switching arm, by means of which a movable bridge electrode is brought so close to the two resting electrodes that a sparkover takes place through the the power transmission of the respective phase is initiated. the radio space which open into the tubular body 1 8, vented through openings. the unmittelbare- access ionized gases and vapors to the main contact point is prevented by the vagina walls 22.

In the lower part of the boiler 2o capacitors and, if necessary, these upstream damping resistors are housed. The capacitors and. Attenuation resistances of each phase are combined in a block 25. The capacitor blocks 25 stand on cross members 26 of an extension pipe 27.28 and 29 are ring conductors on which the direct current connections unite. The inner connecting lines are indicated schematically in FIG. on the right side the direct current connections and on the left side the alternating current connections of a phase. The direct current bushing 3o and the alternating current bushings 33 are mounted in the boiler cover i9. In Figure 2, the places where the bushings sit, indicated with dash-dotted circles. In addition, space is provided for viewing holes 31 through which the contact devices can be viewed. Mirrors 32 make it possible to see the viewing holes 3 from a point of view next to the boiler. The whole converter including the auxiliary devices can be with. the lid i9 can be removed together from the boiler 2o. The contact blocks io are then easily accessible, especially since the capacitor blocks 25 are located in a different boiler zone. In the space within the extension pipe 27, a pump or compressor system shown in the drawing can be attached, which z. B. sucked in purified air through a nozzle in the boiler bottom and, if necessary, promotes under increased pressure through the lower opening of the extension tube 27 into the boiler interior, from where it can be removed for the purpose of constant Umlaufas, for example through a nozzle near the top of the boiler. If the direct current bushing 30 is to be placed in the boiler axis and its extension, ie in the center of the boiler cover 19, in order to achieve greater external distances, the motor 17 can be accommodated in the interior of the extension tube 27.

The drive motor i7 can be used to change the level of control Voltage regulation twisted from the outside by a rotating shaft leading out of the boiler which is omitted in the drawing for a better overview. It can also a device for adjusting the overlap duration during which the Contacts in each of two alternating phases are closed at the same time, provided be. For this purpose z. B. the eccentric 15 with a conical or spherical outer surface executed and be arranged on the shaft 16 displaceably in the axial direction. In order to the overlap duration can always be determined at the same time when regulating the degree of modulation be set to the most favorable value for this. That is the displacement of the eccentric 15 effecting gear can with the device for rotation of Drive motor 17 be coupled. It can also be a facility for independent Regulation of the contact times during operation can be provided externally by z. B. the coupling is not made rigid, but adjustable.

The mode of operation of the converter should be based on a circuit diagram 4 are explained. Then the contact blocks are io to the secondary winding 2 of a transformer, the primary winding of which is not shown, via active, Reactive or apparent resistors connected, the resistance value of which is automatic or periodically changed by automatic control in such a way that the current curve is flattened near zero to facilitate the interruption. For this purpose z. B. chokes 3 are used, the magnetic core 4 at the rated current value is highly saturated and is suddenly desaturated in the vicinity of the current zero value. You can use special, not shown excitation windings with DC or alternating current can be pre-magnetized and controlled in a controllable manner. At the designated 5 The three-phase feedthroughs may be located. Parallel to the interruption points are preferably capacitive secondary paths in the form of the capacitor blocks 25. Die three phases unite on the DC side to form the collecting line 29. The dormant ones Electrodes of the auxiliary switching device 23 are connected to both sides of the contact blocks io and combined on the DC side to form the collecting ring 28, which is connected to the collecting line 29 communicates. The direct current line going out from here contains an -der Point 6 the bushing insulator and leads via a smoothing choke 7 to a DC terminal 8, while the other DC terminal 9 with the star point of the Winding 2 is connected. To protect against harmful fire when the load changes and additional facilities can be provided in the event of a malfunction.

Consider a moment in which the phase drawn on the left is closed and is to be replaced by closing the middle phase. At touches the electrodes of the auxiliary switching device 23 belonging to the middle phase the contact arm rotating in the direction of the arrow passes, so that first the main contacts the subsequent phase must be bridged. A commutation circuit is thus formed. After the main contacts of the middle phase have also closed, take place the commutation process changes in such a way that a current is generated in the subsequent phase and rises to the full DC value while the current is in the outgoing Phase at the same time tends towards its zero value. Near the zero value, a further change in current due to the desaturation of the associated switching inductor 3, 4 delayed, so that the current curve is very flat at this point and the current can be interrupted by opening the main contacts without damaging switchfire can. Since the current is initially via the parallel path until the capacitors are charged a5 is maintained, the major part of the tension remains for the time being on the switching throttle 3, which has a high resistance value, and the recurring Voltage on the main contacts can only increase gradually, so that the danger re-ignition is avoided. The processes described are repeated at the replacement of the other phases.

Since during the closing process of the following phase, the contacts of the previous Phase are initially still closed, the connected to the collecting ring 28 can Electrodes of the auxiliary switching device 23 instead also on the three-phase current side be connected to the contact device of the previous phase. The same It works when only the three-phase connected electrodes are present and the circumferential contact arm is designed, for. B. at an angle of i2o ° 'is bifurcated in the direction of rotation, that it has the electrodes of the detaching one from the other Briefly connects phases. This modified circuit is used in made advantageous use of the arrangement described below.

The arrangement according to FIGS. 5 and 6 differs from the arrangement according to FIGS. I and 2 mainly in that the lines from the alternating current side to the direct current side run in only one direction within the boiler 2o, so that the entire alternating potential is approximately uniform is distributed over the length of the boiler. This is achieved in that the bushings 30 for the direct current supply lines and the bushings 33 for the alternating current supply lines are arranged at opposite ends of the boiler 2o. Since the contact converter according to FIGS. 5 and 6 has six poles and is connected in a bridge circuit, two direct current collecting rings 29 of different potential and two direct current bushings 30 are provided which pass through the cover i9. In the case of a horizontal arrangement, the alternating current bushings 33 could be arranged, for example, on the other end face of the boiler 2o, which could also be designed as a removable cover. This arrangement would have the advantage of being one that is favorable for commutation; namely essentially straight line routing within the boiler, which could easily be continued in a straight line outside the boiler. By these and other means, the leakage reactance of the arrangement can be reduced. The vertical arrangement of the boiler is advantageous for the lubrication of the moving drive parts. Since there is usually less space available at the top, in the arrangement shown the alternating current bushings 33 are inserted at the lower end of the boiler shell on the outside, pointing upwards at an angle. There is ample space here for a larger number of bushings, especially since the boiler diameter is increased in order to gain space for the capacitor blocks 25, which are at the same potential, in addition to the contact blocks io and ioa in the same boiler zone. This is particularly advantageous in the event that the capacitor blocks 25 for controlling the potential distribution at the individual contact points are divided into a corresponding number of small capacitors connected in series with associated damping resistors and these parts are connected in parallel to the individual isolating distances of the contact blocks io and ioa. The numerous connecting lines between the connection points of the individual parts of the parallel path on the one hand and the individual contact pieces on the other hand can be quite short in this way, while such intermediate lines must be relatively long in the arrangement according to FIGS. For this, however, in the arrangement according to FIGS. 5 and 6, access to the contact points of the blocks io and ioa is made more difficult by the capacitor blocks 25 when the device is lifted out. However, this disadvantage can be remedied by the fact that the capacitor blocks 25 are pivotally attached to the contact blocks io and ioa, which is all the easier to carry out because the numerous. Connecting lines between the two only need to be dimensioned for a very small fraction of the nominal current, namely for the amount of current flowing during the flattened part of the current curve and can therefore be very thin and easily movable. The drive motor 17 is installed completely sunk and is accessible through an opening in the boiler cover 19 which is closed by a cover plate 34. The alternating current bushings 33, which are permanently installed on the boiler and therefore cannot be lifted out of the boiler, are connected, for example, via isolating contacts 35 to the inner connecting lines of the contact converter. The isolating contacts can be designed as blade or pin contacts. The boiler 2o stands on feet 36 with rollers 37.

To achieve a twelve-phase ripple, the contact blocks ioa be arranged spatially offset by 3o ° in relation to the contact blocks io, like indicated by dashed lines in FIG. 6. You then form a second converter system for that for the purpose of series connection with special current flattening outside the boiler Resistors a further six AC feedthroughs 33a are required. the Bushings 33 and 33a can be connected to two by 30 ° ' electrically phase-shifted three-phase systems can be connected. The two systems can then be in series or in parallel in a manner known per se be switched. This can be done, especially if the DC-side connecting lines the two systems and any suction throttles should be outside the boiler 2o, further direct current bus lines 29 and a total of up to four direct current bushings 3ö may be required. A common auxiliary switching device can be used for both systems 23, the alternating two poles of one system and two poles of the other system are sufficient connects with each other. However, should the voltage gaps between the only 3o ° ' Spatially spaced apart auxiliary electrodes of the various systems not without an excessive increase in the peripheral speed of the moving Electrode can be made large enough so that each contact system can have a special one Auxiliary switching device are assigned.

Claims (23)

PATENT CLAIMS: i. Contact converter in a closed housing, in particular for high voltage power current, characterized in that a number of and contact points equipped with lift-off contacts (12, 13) in one essentially cylindrical bowls (2o) lie in rows parallel to the bowl axis, which are star-shaped grouped around a drive shaft (16) arranged coaxially in the boiler (2o) are. 2. Contact converter according to claim i, characterized in that the contact device (io to 12) and its drive device (15 to 17) on the cover (i9) of the vertical standing boiler (2o) are attached. . 3. Contact converter according to claim i, characterized characterized in that the contact device consists of blocks (io) in which a number static and moving contacts (ii and 12) with common for several contact points Organs (13) for transmitting the driving force are combined. q .. Contact converter according to claim i, characterized in that the contact device (io .bis 12) of one surrounding the drive shaft (16) and preferably attached to the boiler cover (i9) Tubular body (18) is carried. 5. Contact converter according to claim i, characterized in that that two six-phase contact systems (io and ioa in Fig. 5 and 6) in a common Boiler (2o) arranged in different zones and spatially offset from one another by 3o ° are. 6. Contact converter according to claim i, characterized in that the drive motor (17), especially with a rotatable stand, on the lid side of the boiler (2o) arranged and accessible through an opening in the boiler lid (i9). 7. Contact converter according to claim i, characterized in that the drive motor (17) in a dome (21) is housed on the boiler cover (ig). B. Contact converter according to claim i, characterized in that the contact points bridging capacitors (25) are housed in the boiler (2ö). G. Contact converter according to claim 8, characterized in that the capacitor groups (25) in another boiler zone lie as the contact groups (io, Fig. i). ok Contact converter according to claim 8, characterized in that the capacitor groups (25) in addition to the associated Contact groups (io) lie in the same boiler zone (Fig. 5). i i. Contact converter according to claim i, characterized in that on a free end of the drive shaft (16) the movable part of an auxiliary switching device (23) is arranged, which the for the purpose of phase separation to be formed commutation circuits closes shortly before close the main contacts of the subsequent phase. 12. Contact converter according to claim i i, characterized in that the auxiliary switching device (23) passes through in one Partition walls (22) located within the boiler (2o) partitioned space. 13. Contact converter according to claim i, characterized in that bushing insulators (30, 33, Fig. 1 and 2) for the supply lines to the contact device in the front of the boiler (2o), are arranged in particular in the boiler cover (ig). 1q .. Contact converter according to claim 13, characterized in that the only direct current lead is a three-phase arrangement is arranged in the boiler axis and its extension and that the drive motor at the opposite end of the bowl. 15. Contact converter according to claim i, characterized characterized in that the bushing insulators (30, Fig. 5) for the direct current leads and the bushing insulators (33) for the alternating current leads on opposite sides Ends of the boiler (2o) are arranged. 16. Contact converter according to claim 15, characterized characterized in that some of the bushing insulators, in particular the AC bushings (33), is arranged in the cylindrical part of the boiler (2o). 17. Contact converter according to claim 16, characterized in that bushing insulators (33) on the lower Sit at the end of the boiler (2o) and point upwards at an angle on the outside. 18. Contact converter according to claim i, characterized in that bushing insulators permanently installed in the boiler (2o) (33) are connected to the inner connecting lines via isolating contacts (35). ig. Contact converter according to Claim 6, characterized in that the drive motor is by means of a rotating shaft leading out of the boiler can be rotated from the outside. 20th Contact converter according to Claim 6, characterized in that simultaneously with the Rotation of the drive motor minimizes the overlap of the contact times can be readjusted. 21. Contact converter according to claim 2o, characterized in that that the device for regulating the contact times with the rotating device of the Drive motor is coupled. 22. Contact converter according to claim 2i, characterized by an additional device for independent adjustment of the contact times from outside during operation. 23. Contact converter according to claim i, characterized in that that on one end face of the boiler (2o, Fig._i) inspection holes (31) are provided. 2q .. contact converter according to claim 23, characterized in that the in the boiler lid (ig) provided viewing holes by means of a mirror (32) from a position next to can be seen from the boiler (2o).