DE721019C - System for three-phase power transmission via high-voltage cables - Google Patents

Description

System for rotary current transmission via high-voltage cables For. Three-phase remote transmission. It is advisable to use line arrangements the continuation even in the case of damage and decommissioning of individual conductors enable the transfer of energy. - It is desirable that also after failure individual conductor 'a. as large a part of the transferable in normal operation 'Power noclh transmitted' can be: -The in high-voltage overhead lines Usual execution type he Döppes three-phase current line-only fulfills this task to a limited extent, since in the event of an anis in a circuit only half of the for the double line permissible power are continuously transmitted. can.

In the case of high voltage cable lines, it has been proposed to perform the above task to meet in that parallel to one consisting of three egg-conductor cables Three-phase system, a fourth cable of the same type of blue is laid, which is in normal operation is not used and in the event of a malfunction in one of the other three Cable in its place: is put into operation. This achieves that the full power permissible for (normal operation even in the event of failure one Cable can be transmitted. However, the disadvantage here is that that under normal circumstances the fourth conductor is not used at all.

Furthermore, they are also used for high-voltage cables proposed by six-wire arrangements, with z. B. three. To a three-phase circuit belonging single conductor cables @ must be laid in a common cable trench. Included but there is again the disadvantage that .if one of the two circuits fails only half of the ixn full operation transferable power will be permitted can. It has also already been proposed that the three-phase system .in three from each other to dissolve separate single-phase systems and for each of these single-phase circuits to use one pair of cables laid in each trench. This will be next to others Advantages achieved that if cable faults occur, only one of the three Circuits need to be disconnected. By the two remaining in operation Kajbelpaare can then be transferred, at best,% of the full operating capacity; a closer examination shows, however, that "as a result of the asymmetry that has occurred the power that can still be transmitted after failure of a cable pair is somewhat lower and mostly about 6o0 /, which is full operating power.

The invention is based on the idea that it should be done with consideration on the high installation costs of a high-voltage cable line and on the possible It is advisable to use all available conductors if possible, if there is considerable current heat loss to be used to the full both in normal operation and in the event of a fault for power transmission. So it should be in the event of a temporary failure of a cable ladder or a quay ladder group due to damage edier Störurig the faded cable ladder as a makeshift for the highest possible power transmission can be used without a normally Use unused replacement cable for this. Similar considerations come up not only in the case of a power transmission from a three-phase supply line a three-phase power supply into consideration, but also when the cables as compensating lines can be used between two different turntable parts of any type.

In order to achieve this goal, the ends of the Transmission carbel both with the three-phase supply line and with the three-phase power supply network connected by single-phase voltage transformers that can be switched off, the failure of one cable conductor or group of cable conductors to another Number of symmetrical phases: are switchable, so that at temporarily reduced Number of operational quay ladder by switching the transformer the three-phase system, the Plant remains symmetrically loaded.

If N, = J # U "is the maximum permissible apparent power that can be transmitted per conductor in three-phase operation, then all n-conductors can together under: the assumption cos p = z the power N = n # Np and the n'- remaining operational in the event of a fault Conductor the power N '= n'. N, transferred.

By the standby circuit provided in the context of the invention it is possible at any time, in the event of a temporary failure of a cable ladder or a Cable ladder group in the shortest possible time the transformer, which the transmission of the power from the rotary current supply line to the high-voltage cables and from these to the Mediate three-phase consumption network to switch to a different number of symmetrical phases, so that the three-phase system is symmetrical despite the failure of those cable conductors remains burdened. Conversely, the normal state can easily be restored, as soon as the cable fault has been eliminated. The conversion of the system to one another number of symmetrical phases - is done simply by a simple actuation some switches in correct order.

The drawing illustrates some exemplary embodiments of the invention.

According to Fig. Z are used to transfer energy from the three-phase network R, S, T = in - the three-phase network R ', S', T 'four oil cables r, 2, 3, 4. To this in normal operating condition To be able to fully utilize all of them are single-phase transformers 21, 22 and 21,, 22 ' provided in Scott circuit, which converts three-phase current into four-phase current or convert this back into three-phase electricity. The reactors 44 42 and 4i 42 ' are used for charging current and, if applicable, also for earth fault compensation.

By means of switches rr, 12, 13, 14 or i i ', i2', 13 " 14 ', the cables can be switched off individually in the event of a fault Four-phase system can then be converted into a symmetrical three-phase system with the help of special disconnectors. For this purpose: According to the invention, taps are provided on the secondary windings 34, 32 and 3r ', 32' of the transformer, which are shown in Fig connected disconnectors. 55, 56 and the switch 1 5 give the possibility to drive in four-phase operation with either a closed or with a resolved star point which make up the four-phase system, one will generally prefer a resolution of the star point en. The symmetry of the four-phase system in normal operation is not affected by this. If a cable, for example cable i, is switched off, the following switching is provided: When switches 15 and 55 (Fig. 2) are open, the isolating switch 51 assigned to the failed cable i is inserted, as is the switch 56 at the center tap of the other unvoltage secondary winding. If the switch 15 is now closed, there is a symmetrical three-phase voltage at the terminals 2, 3 and 4 with a suitable design of the transformer taps (FIG. 3). Correct compliance: this switching sequence can be guaranteed by simple relay devices. The star voltage of this three-phase system is ;. As FIG. 3.b shows, the star voltage of the four-phase system according to FIG. 3a is initially about i 5 ° / Q greater than Ils. This increase in voltage in the event of failure of a conductor is inherently beneficial for energy transmission, since in this F.11 not only s / 4, but almost ½ of the power permissible for the four-wire system can be transmitted without current overload.

During a longer repair period, which can result in serious malfunctions may extend over weeks, it may be appropriate to use a permanent overvoltage of 15 0/0 to avoid. For this purpose, for example, on the primary side the transformer still switchable ISternpunktanzapfu.ngen are provided, the one Allow the secondary voltages to be reduced to the desired extent. In the event of failure of the cable 2, 3 or 4, the isolating switch 52, 53 or 54 is inserted accordingly.

FinG. q. - shows another embodiment of the invention. here Six cable conductors z, 2, 3, 4, 5, 6- are used to transfer energy from the three-phase network R, S, T in another, not shown rotary current network. The three transformers 33, 34, 35 at the cable ends are connected to a symmetrical six-phase system and if a pair of cable conductors fails, disconnectors, idie with. corresponding taps are connected to form a symmetrical four-phase system switched. The six cables form three single-phase circuits, which are connected via disconnectors 11, 12, 13, 14, IS, 16 are connected to the Selündärwicklurngen 44 423, 43. The primary windings 23, .24, 25 of this transformer have = taps 26, 27 and «28, which through switches 61, 62, 63 with the. Middle of the primary winding of the following Einphasenümspanners can be connected. The switches 64, 65, 66, 67, 68 and 69 - allow the transformer to be disconnected from the busbar of the network R, S, T. You can also switch off the entire, transformer and cable comprehensive Single-phase circuit can be used.

If one of the three single-phase circuits, for example that of Cable pair 5, 6 fed to transformer 43 as a result of a cable or transformer fault or also z. B. out of order due to overhaul or cleaning work, so the other two circuits are initially due to the asymmetry - .. not next fully exploited. If you now turn the switch 65 off and the formwork 61 on, so transforms the .unsymmetrical system shown in Fig: 5a into a symmetrical one Four-phase phase system according to FIG. 5b. However, this switching makes it possible to use full 2 / s, the full operational performance without any: dwhat asymmetry of the currents or voltages transferred to. The same switchover must of course also be carried out at the other end of the line be made.

Laying the cables in pairs is particularly advantageous consider. With this mode of operation, the smallest possible average results Distances between each one outward and return cable and consequently also the smallest possible values for reactance and additional losses. Approximately occurring Severe cable faults can, in the worst case, be from one cable to the same Trench, overlap second cables that have been laid. When laying three or more cables in a trench, these cables can also be affected, or appropriately large distances must be selected between the individual cables willow: Another major advantage of laying in pairs is the possibility of use. for another type of current, for example for direct current. In pairs Laying can also be used if the possibility is provided to take one of the suffering cables out of operation, but that changes z. B. as third To use a three-phase three-phase current system: In this case, however, must care must be taken that the inductive voltage drop and the additional Losses do not reach undesirably high values. For this reason it is necessary däß an additional return conductor for each cable in the relevant cable trench there is little resistance to the flow. Own the Cable sheaths or armouring made of highly conductive material and of sufficient cross-section, so .these fulfill the stated task. Jackets are used for this purpose, in particular with high loads, often not enough. However, they can be laid in parallel by one Conductors made of highly conductive material are relieved.

Claims (1)

PATENT CLAIMS: i. System for three-phase power transmission via High-voltage cable, characterized in that the ends of the transmission cables both with the three-phase supply line and with the three-phase power supply system single-phase voltage transformers with disconnectable winding taps are connected, the failure of one cable ladder or group of cable ladders to another Number of symmetrical phases can be switched, so that with a temporarily reduced number operational cable ladder by switching over the transformer the three-phase system of the Plant remains symmetrically loaded. -2. Plant according to claim i, characterized in that that when using four cables the winding parts of the transformer on both Cable ends under normal operating conditions to a symmetrical four-phase system are switched and in the event of failure of a cable conductor with the aid of the isolating switch be connected in a symmetrical three-phase system. 3. Plant according to claim 2, characterized in that each of the two .arranged according to the Scottschalfiung type Secondary windings (34, 32 or 31 ', 32') of the transformer with two @symmetnisch for Taps in the middle, which are activated by disconnectors (51, 52, 53, 54) are switched off if the transformer is four-phase when all cable conductors are used is switched, and of which in the event of failure of a cable conductor (e.g. the conductor i). the tap associated with this by inserting its disconnector (51) the middle of the other secondary winding (32) is connected, so that thereby at corresponding position of the tap. a symmetrical three-phase systri (Fig. 2). 4. Plant according to claim 3, characterized in that in the connecting line between the centers of the two secondary windings (31, 32 or 3i ', 32') a switch (15) is arranged, which when all cable conductors and Vierph2senbetrie b of the transformer together with the inserted disconnectors (55, 56) for the middle ones Taps that allow the closure of the star point, and that in the event of failure of one Wire conductor (e.g. i) and switchover of the transformer to three-phase operation on the secondary winding associated with the failing cable - (31) the middle disconnector (55) open and the disconnector (51) of the failing cable conductor (i), first -located tap is closed, whereupon between the latter and the Middle of the other secondary winding (32): by closing the switches (r5, 56) the connection is established '. 5.'Anlage according to claim i, characterized in that that when using six cable ladders the winding parts of the transformer on both Cable ends under normal operating conditions to a symmetrical six-phase system are switched and in the event of failure of a pair of cable conductors with the aid of the isolating switch "can be connected to a symmetrical four-phase system (Fig.4). 6. Appendix according to Claim 5, characterized in that the primary windings (23, 24, 25) of three alternately connected to the three-phase power lines via on / off switches (64-69) Single-phase tensioners (33, 34, 35) whose secondary windings (41, 42, 43) each have a Cable ladder pairs (1-2, 3-4, 5-6) are connected, have taps (26, 27, 28), the by disconnector (61, 62, 63) with the middle, the primary winding of the following Einphasenumspanners can be connected, and @ that when using .all cable conductors idne disconnectors (61, 62, 63) of the taps (26, 27, 28) are open and a symmetrical six-phase system exists, while in the event of failure of a pair of cable conductors (e.g. 5-6) and switching off the associated single-phase transformer (35) the tap (26) of the primary winding (23) of one of the remaining transformer by inserting it its disconnector (61) with the center of the primary winding (24) of the other transformer (34) is connected and the primary switch (65) located next to it is opened, so that with the appropriate position of the taps, a symmetrical four-phase system arises. 7. Antage according to claim i to 6, characterized in that the correct one Sequence of the individual switching stages when switching over the winding parts the Transformer from a symmetrical system of one number of phases to that of the other Number of phases' by. Relay facilities is inevitably made. B. Appendix after fAnspnuch r to 7, characterized in that two single-conductor cables are my common Cable trenches are laid. 9. Plant according to claim 8, characterized in that @ that the cable sheath or the cable armouring made of highly conductive material is sufficient Cross-section, which acts as a return conductor in the event of failure of one of the two cables serves. zo. Plant according to claims 8 and 9, characterized in that in each Cable trench parallel to the single-core cables a bare one or only against corrosion Protected conductor is laid with low resistance, which in the event of failure of one of the both cables together with the cable sheaths serves as a return conductor.