BACKGROUND OF THE INVENTION

The present invention relates to control apparatus for high voltage D.C. transmission systems, for permitting connection of several three-phase current mains having different frequencies, of the type including at least two units operating in parallel during normal operation and each composed of a rectifier group and an inverter group, arranged so that, in unusual situations, one of the units is operated with its energy direction reversed. In such systems, especially for across-line couplings consisting of several units, it is desirable that when the total power is not utilized one of the units be operated to conduct energy in the reverse direction in order to produce a greater than normal total reactive power usage.

SUMMARY OF THE INVENTION

The principal requirements of such apparatus and the central objects of the invention are, on the one hand, to transmit a certain effective power between the lines, and at the same time regulate the frequency of one of the connected lines, and on the other hand, to maintain at a constant level the bus-bar voltage of one of the lines by means of the adjusted reactive power.

These and other objects are achieved in a control apparatus for a high-voltage D.C. transmission system connecting three-phase current systems having respectively different frequencies, the apparatus including at least two units connected to operate in parallel during normal operation and each composed of a rectifier group and an inverter group, and means permitting one of the units to operate with its energy direction reversed in unusual situations, by the provision of: an individual power regulator for each unit connected to receive a desired power signal indicating the magnitude and direction of power transmission by that unit; a common regulator connected to all of the power regulators for supplying thereto, in normal operation, the desired power signal based on the total power for all of the units; a voltage regulator for the three-phase voltage of one of the lines associated with the one unit and providing a signal representative of the magnitude of that voltage; and means switching the control of the regulator for the one unit from the common regulator to the voltage regulator, upon occurrence of an unusual situation, to cause reversed energy direction operation to occur at an energy level proportional to the value of the signal provided by the voltage regulator.

The mechanism according to the invention operates exclusively with closed control loops, and is thus superior to any other conceivable characteristic controls, in that it is independent of the parameters of the energy system.

Since the units are first operated at full D.C. voltage, the best possible effeciency level is maintained. Owing to the fact that the transformer adjustment is removed from operation only on the regulated side, the operation of the reversible unit at reduced D.C voltage can be controlled in such a way that the reactive power on the unregulated side does not increase by the same amount.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a basic circuit diagram of a control apparatus according to the invention disposed at a connecting side of a high-voltage D.C. transmission system.

FIG. 2 is a basic circuit diagram showing the connections between the control system according to FIG. 1, a DC-transmission system and two three-phase alternating current systems, including those connections required for power transmission and control signal generation.

FIG. 3 is a circuit diagram of an embodiment of a regulator used in the control apparatus according to FIG. 1.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

The circuit shown in FIG. 1 includes a connection which, in the illustrated embodiment, is composed of three units E 1, E 2 and E 3. Each unit is connected to a respective, individually associated power regulator 1, 2, or 3. Each regulator supplies a signal representing the nominal, or desired, value, I_d nom, for the respective direct current to be transmitted. Control variables supplied to regulators 1, 2 and 3 are signals P₁, P₂ and P₃, respectively, corresponding to the respective power outputs to be transmitted. At the same time all three regulators are supplied with a reference input representing the desired power, P_nom, for that regulator. The sign of P_nom determines the direction of energy flow and the value of P_nom is itself determined by a total power regulator 4. Regulator 4 produces the signal P_nom as the difference between the predetermined desired total power P_nom Σ and the actual total transmitted power ##EQU1## of the three units. Signal P_nom Σ is produced by summation of a total power signal P'_nom Σ whose value is set by a potentiometer 13, and a signal produced by a frequency regulator 6. This frequency regulator 6 forms a signal component representing the difference between the desired frequency f_nom, which is set for one of the 3-phase voltage lines to be connected, and is set by means of a potentiometer 14, and the frequency f_mains existing in the line.

Unit E 3 provided here is the unit which is, in unusual situations, operated with reversed energy direction. For this purpose the control circuit possesses a switch 9, shown in the normal position, which in an unusual situation switches to the broken-line position to connect the power controller 3 for unit E 3 over to a voltage regulator 5, such that for a raised 3-phase voltage U_mains in one of the connected lines, the power of unit E 3 is raised in the opposite direction. Voltage regulator 5 also receives a reference signal U_nom representing the desired 3-phase voltage. The value of that signal is set by a potentiometer 15.

The removal of unit E 3 from the total power regulator for the purpose of reversed operation is achieved by slowly reducing its desired power value P_nom to zero via element 8. The total power regulator, which continues to be effective for the other units E 1 and E 2, is still able to maintain the total power at a constant level. After the removal of unit E 3 from the power regulator, that unit is supplied, as described above, with its desired power level reference input from the line voltage regulator 5 and thus the reactive power requirement increases for a rise in the desired (effective) power level of unit E 3. As a result, the current and thus the reactive power in units E 1 and E 2 also increase, to compensate the reverse power across unit E 3 under control of the total power regulator 4 effecting power flow in the "normal" direction.

When the power across unit E 3 can be raised no further, the additional remaining reactive power requirement is raised by switching into the electronic voltage limiting regulator of unit E 3. Each unit has such a regulator but they are not illustrated. The voltage limiting regulator for unit E 3, which acts upon the semiconductor element control of unit E 3, is then supplied with its desired value for the voltage limiting level, U_d limit, by the voltage regulator 5, such that at a higher 3-phase voltage, the desired value for the limit of the D.C. voltage is reduced.

The voltage limiting regulator becomes effective only when the highest possible power level, P_max E 3, of unit E 3 is fully utilized. For this purpose, a comparison element 7 is provided and is supplied with a signal e₂ representing the maximum power level, P_max E 3, of unit E 3 and a signal e₁ constituting the control deviation signal from voltage regulator 5, and which delivers the smaller of its two input signals to its output.

The limit level signal U_d limit is derived by a variable-gain amplifier 12 from the difference between the control deviation signal from regulator 5 and the output of element 7 and delivers it to the semiconductor element control of unit E 3. For operation with reversed energy direction, i.e. backward-operation, a time-dependent ramp function signal is provided by function generator 10 upon closing of switch 11 and is delivered to element 8 in order to effect a gradual reduction of the desired power of unit E 3 to zero. Generator 10 is then deactuated after connection is made to voltage regulator 5. Switch 9 is operated by a device which senses whether the gradual reduction of the desired power of unit E 3 has come to zero or not. When the reduction has come to zero, switch 9 is shifted to make connection to voltage regulator 5. Switch 11 then will open again.

The circuit shown in FIG. 2 includes the power transmission lines between two three-phase current mains 18 and 19 having different frequencies, with the three units E 1, E 2 and E 3 operating in parallel during normal operation. Unit E 3 is shown in detail, consisting of power switches 22, 23 (to cut off the unit from the mains 18 and/or 19), transformers 20, 21, a rectifier group 24, a smoothing coil 26 and an inverter group 25. In case energy direction is reversed, group 24 operates as an inverter while group 25 operates as a rectifier.

Control signals for the control apparatus according to the invention are derived via a voltage transformer 28 (signal representative of the voltage of the mains 18) and a current transformer 27 (signal representative of the alternating current through group 24) as well as a voltage divider 29 (signal representative of the D.C. voltage U_d) and a shunt 30 (signal representative of the direct current I_d). The signal from voltage transformer 28 is supplied as the actual mains voltage U_mains to the voltage regulator 5, and transformed by a voltage to frequency transformer 16, as the actual mains frequency f_mains to the frequency regulator 6. The other connections of regulators 5 and 6 are as shown completely in FIG. 1.

The signal P₃ is obtained by supplying a multiplier 17 with the signals U_d and I_d from the voltage divider 29 and the shunt 30 respectively. The signal P₃ is summed up at 32 together with signals P₂ and P₁ which are derived from units E 1 and E 2 the same way P₃ is from unit E 3. These three signals summed up result in the actual total transmitted power ##EQU2## which is supplied to the total power regulator 4. Regulator 4 produces the signal P_nom as the difference between the actual total transmitted power ##EQU3## and the predetermined desired total power P_nom Σ (not shown in FIG. 2). Signal P_nom, representing the desired power, is fed into power regulator 3 together with signal P₃ representing the actual transmitted power by unit E 3.

The output signal of regulator 3 is the desired value I_dnom of the direct current flowing in unit E 3. Signal I_dnom is fed into the current control regulator 37 as well as the actual value of current I_d derived from shunt 30. A signum control device 38 senses the algebraic sign of signal P_nom thus supplying according to the sign a supplementary value -ΔI_d to the output of the power regulator 3.

The output of regulator 37 is the desired firing angle α'_nom for the pulse timing device 31 which controls the firing of the valves of group 24 by using the voltage U_mains derived from voltage transformer 28. The desired firing angle α'_nom may be corrected to a value α_nom first of all by a comparison element 35 the output signal d which is the smaller of the signals g₁ or g₂ ; g ₁ being the signal α'_nom. Signal g₂ is the output of the D.C. voltage control device, or voltage limiting regulator, 36 comparing the actual D.C. voltage U_d derived from voltage divider 29 with the desired value which is the limit level signal U_dlimit coming from amplifier 12 shown in FIG. 1.

Signal α_nom is obtained as output signal b by another comparison element 33, this signal being the smaller of the input signals c₁ or c₂. Signal c₂ is the output signal d of element 35. Signal c₁ is the output signal of the extinction angle γ-control device 34, which regulates the extinction angle γ to a constant value using the mains voltage U_mains via voltage transformer 28 and the alternating current through group 24 via current transformer 27.

Regulator and comparison elements as described for the left hand side of FIG. 2 in connection with the pulse timing for group 24 are to be used in the same way in connection with the pulse timing for group 25. This is not shown in detail but just indicated.

In FIG. 3 is shown a circuit diagram of regulator 1. The input signals P_nom and P₁ are fed into an amplifier 39 via resistors 40 and 41. The second input is grounded via resistor 43. A resistor 42 and a capacitor 44 are used for feed-back. The output is the desired value I_dnom. All regulators used within the control apparatus according to the invention do have similar circuits.

It will be understood that the above description of the present invention is susceptible to various modifications, changes and adaptations, and the same are intended to be comprehended within the meaning and range of equivalents of the appended claims.