DE632813C - Equipment for the operation of electrical feeders - Google Patents

Description

Equipment for the operation of electrical feeders The patent 628 2r4 relates to a device for operating electrical feeders, in particular of uniforms who come from a common or several separate primary networks on a common secondary network route, such as the contact wire of a Railway line, work in such a way that each feeder works preferably those assigned to it Section supplied with energy. This is done by special control devices achieved which is the sum or difference of the services provided at the ends of the one Feeder-fed route sections occur at a predetermined value keep.

The invention now consists in applying the same control method to the Apply reactive load control, i.e. the reactive power of the feeder the control organs to influence which the power sum or difference at the ends of the Keep the fed route sections at a predetermined value. It can of course also both, the active as well as the reactive power, according to the same criteria be distributed. This type of regulation is used in the case of food works, the contact wire lines supply in electric train operation, make use of it. Especially during the Train start-up times occur considerable reactive power according to the invention primarily supplied by the feeder belonging to the overhead wire that is currently under load should be and not from the neighboring sections, otherwise they themselves will be in trouble regarding the voltage maintenance and the supply of your own section with Reactive load can occur. If, on the other hand, the load on the converter in the feeder reaches its limit, then the neighboring sections should intervene to provide support. This is achieved by the fact that the limit power is exceeded by blocking the active and reactive power control is prevented.

Since the reactive load control acts on the excitation of the machine, this but also influences their tension in the same way, care must be taken to ensure that that, despite the reactive load regulation, the voltage in the network is within the permissible fluctuations remain. The reactive power control is therefore disabled if the Voltage in the fed section is outside the permissible limits. In first and foremost will for this blocking the voltage on the Use both-Eisäen- -d'e'r ", 'fed routes and the mean value of these let both tensions be effective. So in the first; line the tension is on kept to the emergency. Now step here larger @. Reactive power shifts then this control procedure is blocked. The reactive power-dependent control process takes its place and makes sure that each section of the meal is replaced by its own Factory is supplied with reactive power. Here, of course, voltage fluctuations can occur occur that are also accepted within certain limits in rail operations. If the voltage reaches or exceeds one of the two to a converter station- appropriate coupling points the permissible limit, then the higher regulation of the Converter voltage blocked; the voltage reaches or falls below the lower Limit, then the downward movement of the converter voltage is put out of operation. -In both cases, the regulation that regulates the voltage in the allowed range.

The reactive power control of the individual converter stations is expedient depending on the direction of the reactive power flow at the coupling points the feed sections in the same way as in the main patent regulating the active powers. If the reactive power flows out of the feed section in both coupling points, this means that both neighboring sections are supplied with reactive power. If the voltage falls below the upper voltage limit in the neighboring sections supplied is; what is determined by measuring the voltage at the coupling points, then the reactive power is increased at a moderate control speed.

On the other hand, if the reactive power flows in the same way at both coupling points Direction, i.e. at one end into the section; at the other end the section out, then the reactive power control depends on the ratio of the both services. If the power flowing out of the section is greater, then the reactive power supply is increased at a moderate speed. at The same rule applies to equality of the two services to support the "supplied" neighboring section and your own reactive power consumption to reduce. However, more reactive power flows into the section than it does out of it out, the reactive power supply is at high control speed to increase until the services flowing out and in again, for example are equal to each other. If reactive power is fed into the section via both coupling points flows into it, then there is a particularly strong reactive power requirement, so that the Reactive power supply with `` highest control speed as long as - ''. Increased must be until, provided that the direction of performance remains the same, the total of the two reactive powers has dropped to zero at the line limits, since then the converter plant the reactive power demand arising in its section itself covers. In all cases, of course, the regulation is based on the maximum permissible voltage fluctuations set a limit.

If the direction of the reactive power flow changes during regulation, then always finds the necessary rule according to the new conditions Use. It is a prerequisite in all cases that the high control speed is a multiple of the moderate control speed, so that the rapid control process has already ended before further voltage changes in the neighboring sections appeared.

There is an upper limit for regulating the converter voltages up set by the permissible voltage fluctuations. However, there is a risk that the highest voltage value is always observed. But if possible, a To achieve a return to the nominal voltage, one will always use pure voltage regulation (Mean value control) take effect when the difference in power is on the coupling points when the output reactive power outweighs a fixed one Value has decreased. For example, when idling or when the load on the route is constant under the influence of this control all converters are adjusted to their nominal value.

In Fig. 1 an embodiment of the invention is shown. A converter 5o supplies a line that is connected to the neighboring sections at the coupling points I (2, I (3). Reactive power meters 54 52 are installed at both points I (2, I (3, the contacts of which are in series with a coil of the differential relay 3 and 6 as well as the actuating relays 4, 7, 9 and II are located. The contacts 9 and 11 apply the voltage to the relay 12 via the current source 1o and the contacts 31, thereby causing the voltage to be increased quickly The circuit of the relay 8 fed from the current source 5 via the contacts 31 and thereby cause a slow upward voltage regulation. The contacts 14 of the differential relay 6 are parallel to the contacts of the relay 11, and the contacts 15 of the differential relay 6 are parallel to the contacts of the relay 4 In a corresponding manner, the contacts 16 of the relay 3 are connected parallel to the contacts of the relay 7, the contacts 17 of the relay 3 are connected parallel to the contacts of the relay 9 tet. The movable systems of the differential systems 3 and 6: «are held in the middle position by springs 13 and 18, respectively. The contacts 14 and 16 are actuated when the reactive power LB2 occurring at the coupling point K2 predominates, the contacts 15 and 17 when the power LB occurring at the coupling point Ks is greater than LB2.

If the reactive power is now directed outwards at both ends of the line is, then the direction relays 51, 52 take the position shown. From the relay 51 is consequently a circuit via the contacts i, the right winding of the Differential relay 3 and relay 4 made to earth. The relay 4 closes its contact and puts the battery 5 to earth. A circuit is established from the relay 52 via contacts 2, the right winding of the differential relay 6 and the relay 7 made to earth. The relay 7 closes its contact and thus sets the Relay 8 on. As a result, the voltage is slowly increased of converter 50.

Is the reactive power on. two coupling points 1 (2, kg inward, then the direction relay 51 beats to the right, the direction relay 52 to the left. The direction relay 5, creates a circuit across the left coil of the differential relay 6 and the relay 9. This relay closes its Contact and thus connects the battery io to earth via the contact 31. Furthermore, the relay 52 completes a circuit via the left coil of the relay 3 and the relay ii and thus energizes the relay 12. This brings about a rapid increase in the voltage.

If the reactive power is directed to the right in K2, and also to the right in K3, then the relay 51 strikes to the right and the relay 52 also to the right. As a result, a circuit is established from earth via contact i, the left coil of the Relay 6 and the relay 9 made and the relay 9 made to respond. A second circuit is made from earth via contact 2, right coil of relay 6 and the relay 7 is formed to earth, then the relay 8 is connected to earth. It is now to distinguish whether the power LB, is greater than the power LB, in this Case strikes the relay 6 after overcoming the spring force 13 to the left and this closes contact 14. This applies voltage to relay i2. A rapid increase in voltage occurs., However, if LB3 is greater than LB2, then if the differential relay 6 moves to the right, its contact 15 and closes sets the command relay 8 under current, because the contacts of the relay 7 are also closed are. As a result, the voltage is only slowly regulated upwards.

If the reactive power in K2, K3 is directed to the left, then a Circuit from earth via the contact i, which is turned to the left, the right winding of relay 3 and relay 4 formed to earth. It is also about the contacts : 2 the relay i i energized. If LB is now greater than LB3, then this hits: Relay 3 to the left and closes its contact 16, whereby the command relay 8 to voltage is placed, since the contact of the relay q. closed is. With moderate Control speed increases the voltage. If LB3 is greater than LB2, then beats the relay 6 to the right and closes its contact 17. As a result the command relay 12 via the closed contact 3 i: voltage applied, there relay i i has also picked up. As a result, it sets a high control speed a. The standard procedure thus corresponds to the demands made, namely that when the converter is used to supply its own section with reactive power should be used, the regulation takes place particularly quickly.

In addition to the scheme shown in Fig. I, depending on the Reactive power is also regulated depending on the voltage, if at one of the coupling points K2, K3 the upper or lower voltage limit is achieved. With i9 and 21 are indicated in Fig. 2 voltage relays, which are dependent on respond from the remote signaled voltage of the two coupling points. At too high Voltage values are the contacts: 2o, 22, if the voltage values are too low, the contacts 24, 25 actuated. As a result, the relays 23, 26 are actuated, which increase or decrease regulation cause the tension. When the relay 29 responds, the contacts 30, 31 Fig. i, which interrupt the circuit of the command relays 8, 12.

Another relay 53 is influenced by the mean value of the two voltages at the coupling points K2, I (3, i.e. from U2 + U3 bb-2. If this mean value is too high, then the relay 23 via the contacts 54, the mean value is too small The relay 26 is then connected to voltage via the contacts 55. The prerequisite here is that the relays 8 and 12 have not responded so that the contacts 27, 28 are closed the measuring device 19 or 21 its contact 20 or, 22. Then the command coil 23 is connected to voltage and the voltage of the converter is reduced its contacts 30 and 31. As a result, the command relays 8 and 12 are de-energized and thus interfering commands are avoided.

If the voltage is too low, contact 24 or 25 resp. also both closed, which actuated the command coil 26 and the converter voltage is increased, optionally with moderate or high control speed.

Is the difference in reactive power so small that the pointer the relay 3 or 6 cannot overcome the forces of the springs 13 or 18, .then The voltage regulation is of course left to the mean value control relay 53. If, however, the spring forces are overcome, then flows into the command relay 8 and i2 current; however, this will open the contacts 27 and 28 and the mean value control interrupted. However, the limit value control is still maintained.

For the control process, it is irrelevant whether the energy transfer takes place via converters or converters.

Claims (7)

PATENT CLAIMS: i. Device for the operation of electrical, feeder works using control organs which keep the total or difference in power at the ends of the fed route sections at a predetermined value, according to Patent 628 21q., Characterized in that the control organs (51,52) by the reactive power the feeder for the network route (contact wire) are affected. 2. Control device according to claim i, characterized in that at the same time the Active and reactive power in the control organs is effective. 3. Control device according to Claims i and 2, characterized by devices (ig, 2i) which the reactive load control relay (8, 12) block when the voltage in the powered section is outside the permissible voltage limits. q .. Control method according to Claims i and 3, characterized in that the blocking devices (i9, 21) are dependent on the voltages (U2, U3) at both ends (K2, K3) of the fed path. 5. Control device according to Claims i to q., Characterized by additional control elements (23, 26), which when the permissible stress limits are exceeded, the stress in bring the permissible limits. 6. Control device according to claim i to 5, characterized characterized in that the control speed is a maximum when a resulting Reactive power flows into the section. (Actuation of relay 1a.) 7. Control device according to claim i to 6, characterized in that in one at the end, at the the reactive power flowing out at the other end, the reactive power control relays (8, 12) are blocked and the voltage control (53) only depends on the mean value of the voltages «J" U3) depends on the two changes in performance, provided that the difference of the two reactive powers do not have a specific, possibly adjustable value exceeds and therefore does not cause the organs (3, 6) to respond.