FR3119274A1 - Method for configuring a high voltage direct current installation - Google Patents

Abstract

The invention relates to a method for configuring a high voltage direct current installation, said installation comprising a first main terminal (A) and a second main terminal (B), a first electrical conductor (1) which comprises a first terminal ( 1_1) and a second terminal (1_2) which is connected to said second main terminal (B), said method consisting in particular in adding a second electrical conductor (2), which comprises a first terminal (2_1) and a second terminal (2_2) which is connected to said second main terminal (B), and inserting a three-terminal (X, Y, Z) power converter (PC), so that its first terminal is connected to the first main terminal (A), its second terminal (Y) is connected to the first connection terminal (1_1) of the first electrical conductor (1) and its third terminal is connected to the first connection terminal (2_1) of the second electrical conductor (2). Figure to be published with abstract: Figure 2

Description

Method for configuring a high voltage direct current installation

Technical field of the invention

The present invention relates to a method for configuring a direct current high voltage installation and to said direct current high voltage installation, configured using said method.

State of the art

It is known to transmit power between two terminals A, B of a high voltage direct current installation (also called HVDC installation) using a first electrical conductor 1, made in the form of a cable, a line overhead or more generally of a connection made up of sections of cables and overhead lines. This link is sized to transmit a given electrical power, referenced P on the .

An upgrade of the installation is sometimes necessary when a greater power must be transmitted between the two terminals A, B, the excess power to be transmitted being denoted ΔP. In this situation, a classic solution consists in adding a second electrical conductor 2 in parallel with the first electrical conductor 1, as shown in the . As can be seen on the , the two conductors 1, 2 in parallel thus make it possible to transmit the total power P+ΔP between the two terminals A, B. However, the electrical resistance ratio between the two conductors means that the total electrical power P+ΔP transmitted does not go not necessarily be distributed so that the first electrical conductor 1 will transmit the power P and the second electrical conductor the power ΔP, as illustrated in the . On this , the first electrical conductor 1 will thus transmit a power P1 different from P, and the second electrical conductor will transmit a power P2 different from ΔP. It emerges from this that the second electrical conductor 2 added will most certainly have to be sized to transmit a power greater than ΔP, this in order to ensure that the power P+ΔP is transmitted, whatever the resistance ratio between the two conductors. With such an installation, one of the two electrical conductors is required to transmit electrical power which is always less than its maximum capacity and is therefore not used optimally.

There illustrates this problem. On this , the installation transmits the total power PT. The first electrical conductor 1 transmits the power P1 with the current I1 and the second electrical conductor 2 transmits the power P2 with the current I2. The total power to be transmitted is denoted PT. There also shows, for each conductor 1, 2, the electrical resistance R1, R2, the thermal resistance between the conductor and the ambient Rth1, Rth2, the temperature of the electrical conductor T1, T2 and the power losses Ploss1, Ploss2.

Since the two conductors are connected in parallel, their voltage drop should be the same. So we have : (1)

Knowing that , starting from (1) above, we then obtain: (2)

For each conductor, the thermal losses can be expressed as follows: (3) (4)

These relationships show that if , the first electrical conductor 1 will concentrate more current and will generate more losses. It should be noted that the electrical resistance of an electrical conductor is linked to its section, to its material of manufacture and to the temperature of the conductor. For each electrical conductor, its temperature can be expressed as follows with Room temperature : (5) (6)

By combining relation (3) with relation (5), and relation (4) with relation (6), we understand that if we consider that , and that the thermal resistances are equal ( = ), temperature of the first electrical conductor will be higher: (7) (8)

The dimensioning of an electrical conductor must be chosen by the maximum power that it can transmit at its maximum temperature.

Thus it can be concluded that in an installation with two electrical conductors in parallel, the first electrical conductor 1, which has the lowest resistance, will be caused to transmit the highest electrical power and will have a higher temperature. The maximum power that the assembly can transmit will therefore be linked to the maximum temperature of this conductor. On the other hand, the second electrical conductor 2, which has the highest resistance, will have to transmit less electrical power than the first electrical conductor 1, at a temperature lower than its maximum temperature. This second electrical conductor 2 will therefore be used well below its maximum capacities while the first electrical conductor 1 will be stressed close to its maximum capacities.

Of course, if the two electrical conductors have identical electrical resistance, the power will be distributed equally in each electrical conductor.

There illustrates the above findings with a numerical example.

In this example, initially, before upgrading, the installation must transmit a power of 0.7 GW and the first electrical conductor 1 transmits the power P=0.7 GW by being dimensioned (with a section S ₁ of 1200 mm ² of copper) to transmit the power P ₁ 'of 0.71 GW. The installation must be modified to pass an additional power ΔP with ΔP=0.9GW. For this, a second electrical conductor 2 is mounted in parallel with the first electrical conductor 1 with a section of 2400 mm ² . To transmit the total power P _T (equal to P+ΔP=1.6 GW), the second electrical conductor 2 must be dimensioned to pass a power greater than ΔP=0.9 GW (the second electrical conductor 2 is dimensioned in this case for transmit a power P ₂ 'of 1.05 GW). This is linked to the fact that the second electrical conductor 2 has a section S ₂ greater than that of the first electrical conductor 1, which gives it a lower electrical resistance than that of the first electrical conductor 1 and therefore a tendency to concentrate more power. electrical than the first electrical conductor 1. It follows that when the power P _T of 1.6 GW must be transmitted, the second electrical conductor 2 will be required to transmit a power P ₂ close to its nominal power (P ₂ =1.04 GW) then that the first electrical conductor 1 will be underused, by transmitting only the complement, that is to say a power P ₁ of 0.56 GW whereas it is sized to transmit a power of 0.71 GW. Furthermore, it can be noted that even if the first electrical conductor 1 proves to be underused, the total power of the installation cannot however be increased. An additional power would overload the second electrical conductor 2 and not the first electrical conductor 1, the total power transmitted not being able to be distributed in an appropriate manner between the two electrical conductors taking into account their respective dimensions. In this example, the maximum admissible temperature is considered to be 70°C. It can be seen that the second electrical conductor 2 is used close to this temperature, therefore close to its maximum capacity, whereas the first electrical conductor 1 is used at a lower temperature. Furthermore, the first electrical conductor 1 carries a current lower than its maximum capacity and increasing the electrical power transmitted would lead to overheating of the second electrical conductor 2 and not of the first electrical conductor 1.

The object of the invention is therefore to propose a solution making it possible to configure a high voltage direct current installation so that it is able to pass a surplus of power, without having to oversize it and with the aim of being able to exploit each driver to the maximum of his or her abilities.

This object is achieved by a method for configuring a high voltage direct current installation, said installation comprising a first main terminal and a second main terminal between which is transmitted a so-called input/output electrical power, a first electrical conductor which comprises a first connection terminal and a second connection terminal, its second connection terminal being connected to said second main terminal, said first electrical conductor being sized to transmit a first rated electrical power, said method comprising:

• Add a second electrical conductor, which comprises a first connection terminal and a second connection terminal, its second connection terminal being connected to said second main terminal, said second electrical conductor being sized to transmit a second nominal electrical power,
• Add a power converter which comprises a first terminal, a second terminal and a third terminal, said power converter being inserted in said installation so that its first terminal is connected to the first main terminal, its second terminal is connected to the first connection terminal of the first electrical conductor and its third terminal is connected to the first connection terminal of the second electrical conductor, said power converter also comprising a first voltage source and a second voltage source, and controllable means of exchange of energy between the first voltage source and the second voltage source,
• Configuring a control unit of the power converter to make it capable of controlling the power converter with a view to adjusting the voltage supplied by said first voltage source in series with the first electrical conductor and the voltage supplied by the second voltage source in series with said second electrical conductor and distributing said input/output electrical power in the first electrical conductor and in the second electrical conductor, taking into account the first nominal electrical power that the first electrical conductor is able to transmit and the second rated electrical power that the second electrical conductor is able to transmit.

According to one feature, the second electrical conductor is dimensioned to transmit a second nominal electrical power distinct from the first nominal electrical power.

According to another feature, the method also consists in inserting a device for putting the power converter into service/out of service, and in controlling said device for putting into service/out of service to insert the power converter between the two main terminals or the get around.

The invention also relates to a direct current high-voltage installation which comprises a first main terminal, a second main terminal between which is transmitted an electrical power referred to as input/output, a first electrical conductor which comprises a first connection terminal and a second connection terminal, its second connection terminal being connected to said second main terminal, said first electrical conductor being sized to transmit a first nominal electrical power, said installation being configured according to the method as defined above, by integrating:

• A second electrical conductor, which comprises a first connection terminal and a second connection terminal, its second connection terminal being connected to said second main terminal, said second electrical conductor being sized to transmit a second nominal electrical power,
• A power converter which comprises a first terminal, a second terminal and a third terminal, said power converter being inserted in said installation so that its first terminal is connected to the first main terminal, its second terminal is connected to the first terminal connection of the first electrical conductor and its third terminal is connected to the first connection terminal of the second electrical conductor, said power converter also comprising a first voltage source and a second voltage source, and controllable means for exchanging energy between the first voltage source and the second voltage source,
• A control unit for said controllable means,
• Said controllable means of the power converter being controlled by the control unit to adjust the voltage supplied by the said first voltage source in series with the first electrical conductor and the voltage supplied by the second voltage source in series with the said second electrical conductor and distributing said input/output electrical power in the first electrical conductor and in the second electrical conductor, taking into account the first nominal electrical power that the first electrical conductor is capable of transmitting and the second nominal electrical power that the second electrical conductor is able to transmit.

According to one feature, the first voltage source is created between the first terminal and the second terminal of the power converter and the second voltage source is created between the first terminal and the third terminal of the power converter.

According to another feature, said controllable means comprise switching means connected between the second terminal and the third terminal of the converter and a current source connected between the first terminal of the power converter and a midpoint of said switching means.

According to a particular embodiment, the switching means are chosen to be non-reversible in current and non-reversible in voltage.

According to another particular embodiment, the switching means are chosen to be reversible in current and reversible in voltage.

According to another feature, the current source comprises an inductor.

According to another feature, the first voltage source comprises a first capacitor and in that the second voltage source comprises a second capacitor.

According to an advantageous embodiment, the installation comprises a device for commissioning/decommissioning the power converter and a control unit configured to control said connection/disconnection device with a view to inserting the power converter between the two main terminals or circumvent it.

Brief description of figures

Other characteristics and advantages will appear in the detailed description which follows given with regard to the appended drawings in which:

• FIGS. 1A to 1D illustrate the principle of operation of a high voltage direct current installation, according to the state of the art;
• FIG. 2 illustrates the architecture of the high voltage direct current installation according to the invention;
• FIGS. 3 and 4 schematically represent the architecture of the power converter used in the high voltage direct current installation of the invention;
• FIG. 5 represents a first architecture of the power converter inserted in the high voltage direct current installation of the invention;
• FIGS. 6A and 6B illustrate the principle of operation of this first architecture of the power converter inserted in the high voltage direct current installation;
• Figures 7 and 8 show two equivalent embodiments of the architecture of Figure 5;
• FIG. 9 represents a second architecture of the power converter inserted in the high voltage direct current installation of the invention;
• FIG. 10 represents a third architecture of the power converter inserted in the high voltage direct current installation of the invention;
• FIG. 11 illustrates the principle of operation of the high voltage direct current installation according to the invention;
• FIG. 12 represents an alternative embodiment of the direct current high voltage installation according to the invention;
• Figure 13 represents a diagram illustrating the operating principle of the installation of Figure 9;

Detailed description of at least one embodiment

The invention applies to a high voltage direct current installation (also called HVDC installation for "High Voltage Direct Current").

The installation comprises a first main terminal A and a second main terminal B between which electrical power is transmitted (from A to B or from B to A – for simplification, it is considered below that the power is transmitted from A to B ). It comprises a first electrical conductor 1 comprising a first connection terminal 1_1 and a second connection terminal 1_2. Its second connection terminal 1_2 is connected to the second main terminal B.

Initially, the installation, consisting of a single first electrical conductor 1, is intended to transmit a nominal power equal to P.

This first electrical conductor 1 is dimensioned sufficiently to transmit the nominal power P.

By the term “size”, it is meant that an electrical conductor has characteristics (in particular type of material, cross-section, maximum temperature) which allow it to transmit a given nominal electrical power.

To ensure that the installation can transmit an electrical power greater than P, corresponding to a power surplus ΔP, a first aspect of the invention consists in upgrading the installation. For this, with reference to the , it is thus a question of adding to the installation:

• A second electrical conductor 2, and
• A PC power converter.

The power converter PC has three electrical terminals, a first terminal X, a second terminal Y and a third terminal Z.

The second electrical conductor 2 comprises a first connection terminal 2_1 and a second connection terminal 2_2 connecting to the second main terminal B.

The PC power converter is inserted into the installation as follows:

• Its first terminal X is connected to the first main terminal A;
• The first connection terminal 1_1 of the first electrical conductor 1 is connected to its second terminal Y;
• The first connection terminal 2_1 of the second electrical conductor is connected to its third terminal Z;

The power converter inserted in the installation is thus intended to be controlled to distribute the electrical power in the two electrical conductors.

Considering that the total power to be transmitted is P+ΔP, the power converter PC makes it possible to guarantee that the first electrical conductor 1 transmits the electrical power P and that the second electrical conductor 2 transmits the electrical power ΔP.

The insertion of the power converter PC makes it possible to ensure the use of a second electrical conductor 2 dimensioned as accurately as possible to pass the excess power ΔP, without unnecessary oversizing, thus limiting the additional costs.

With reference to the , the power converter PC can comprise a first voltage source V1 which, on command, can be connected in series with the first electrical conductor 1 and a second voltage source V2 which, on command, can be connected in series with the second electrical conductor 2. The power converter PC also comprises means 3 configured to ensure an exchange of electrical energy between the two voltage sources V1, V2, with a view to distributing the total current IT in each electrical conductor 1, 2 and distributing the electrical power in each electrical conductor, taking into account the dimensioning of each electrical conductor. On the , the two dotted vertical arrows illustrate the principle of energy exchange between the two voltage sources V1, V2.

The possible insertion of a voltage in series with each electrical conductor 1, 2 makes it possible to modify the voltage at the terminals of the two electrical conductors and therefore to distribute the currents in an appropriate manner in the two electrical conductors. Thanks to the exchange of energy between the two voltage sources, the current distribution is modified without generating significant losses. Indeed, the power absorbed by the source in series with the electrical conductor whose current is to be reduced is transmitted to the other voltage source.

According to an advantageous aspect of the invention, none of the terminals X, Y or Z of the power converter PC is connected to earth. In HVDC-type installations, the conductors are placed at potentials with respect to earth of several tens of kilovolts or even several hundreds of kilovolts (voltages between terminal A and earth or between terminal B and earth). In order to produce the expected effect (control of the distribution of the currents between the two electrical conductors 1, 2 of the installation), the voltages between the terminals X, Y and Z are of the same order of magnitude as the voltage drops at the terminals of these electrical conductors (voltage between the two main terminals A and B) is of the order of a few hundred volts, or even a few kilovolts. Thus, the voltage dimensioning of this converter is reduced and its production is facilitated.

To ensure energy transfer between each voltage source, with reference to the , the means 3 may comprise a current source 30 and switching means 31 arranged and controlled to allow connection of said current source 30 in parallel with the first voltage source V1 or in parallel with the second voltage source V2.

It should be noted that, according to the mesh law, imposing a voltage between the terminals X and Y of the converter on the one hand and a voltage between the terminals X and Z of the converter on the other hand, amounts to imposing the voltage between the terminals Y and Z of the converter. Thus, a device imposing voltages between terminals Y and Z on the one hand and X and Z on the other hand would produce the same effect and in reality corresponds only to another way of describing the device described above.

The switching means 31 can include one or more power switches. The number of power switches, their arrangement and their characteristics depends on the sign of the currents I ₁ and I ₂ in each electrical conductor 1, 2 and on the polarity of the voltages inserted in each electrical conductor. A control unit UC of the installation is responsible for controlling each power switch of the converter PC, with a view to obtaining the distribution of the currents between its two terminals Y and Z.

Current source 30 may include at least one inductor L.

According to a particular aspect of the invention, with reference to the , the general architecture of the PC power converter can be as follows:

• The first voltage source V ₁ is connected between the first terminal X and the second terminal Y of the converter;
• The second voltage source V ₂ is connected between the first terminal X and the third terminal Z of the converter;
• The switching means 31 are connected between the second terminal Y and the third terminal Z of the converter;
• The current source 30 is connected between the first terminal X of the converter and a midpoint M of the switching means;

Each voltage source is created using one or more capacitors (C ₁ , C ₂ , C ₃ ) connected in a suitable manner between the terminals X, Y, Z of the power converter PC.

Based on the above principles, the PC power converter can be made according to different architectures.

Figures 5 to 10 show several possible architectures for the realization of the power converter.

The architecture chosen for the converter will depend in particular on the degree of current and voltage reversibility which it is desired to have.

There shows a first architecture, non-reversible in current and non-reversible in voltage. In this first architecture:

• The first voltage source V ₁ includes a first capacitor C ₁ .
• The second voltage source V ₂ includes a second capacitor C ₂ .
• The first capacitor C ₁ is oriented so as to be able to create a positive voltage in series with the first electrical conductor 1.
• The second capacitor C ₂ is oriented so as to be able to create a negative voltage in series with the second electrical conductor.
• The switching means 31 comprise an electronic transistor T ₁ (for example of the IGBT, IGCT, GTO, MOSFET type, etc.) and a diode D ₁ . For transistor T ₁ , its gate is controlled by the installation's control unit UC according to a determined control law (see below), its collector is connected to the midpoint and its emitter is connected to the second terminal Y of the converter. The diode D ₁ is connected between the midpoint M and the third terminal Z of the converter and oriented conductive from the midpoint M to the third terminal of the converter.
• The current source is formed by an inductance L, connected between the first terminal of the converter X and the midpoint M of the switching means.

This first architecture can be used when the total current IT enters through the first terminal X of the converter and the two currents I1, I2 leave the converter PC respectively through its second terminal Y to circulate in the first electrical conductor 1 and through its third terminal Z to circulate in the second conductor 2. This architecture makes it possible to obtain a distribution of the currents different from the distribution which would be observed if the conductors were placed in parallel as on the . On the , the capacitors C1, C2 are connected so as to create a positive voltage in series with the first electrical conductor 1, to lower the current I1 and a negative voltage in series with the second electrical conductor to increase the current I2. This solution can be used when the conductor likely to be overloaded (that is to say the conductor with the lowest electrical resistance) is the first electrical conductor 1. It is of course possible to reverse the architecture to discharge the other electrical conductor.

There and the illustrate the operating principle of this first architecture, by presenting the path followed by the currents (represented in gray) in the different branches of the power converter PC while neglecting the current oscillations in the inductor.

• In FIG. 6A, transistor T ₁ is in the closed state. The total current I _T (=I ₁ +I ₂ ) enters via the first terminal X of the converter, crosses the inductance L then the transistor T ₁ . Part of this current I _T leaves through the second terminal Y of the power converter PC, forming the current I ₁ present in the first electrical conductor 1. Another part of the current I _T passes through the first capacitor C ₁ , then the second capacitor C ₂ to exit through the third terminal Z of the power converter PC, forming the current I ₂ in the second electrical conductor 2.
• In FIG. 6B, transistor T ₁ is in the open state. The total current I _T (=I ₁ +I ₂ ) enters via the first terminal X of the power converter PC, crosses the inductance L then the diode D ₁ . Part of this current I _T leaves through the third terminal Z of the power converter PC, forming the current I ₂ present in the second electrical conductor 2. Another part of the current I _T passes through the second capacitor C ₂ , then the first capacitor C ₁ to exit through the second terminal Y of the power converter PC, forming the current I ₁ present in the first electrical conductor 1.

This first architecture is to be considered in a non-restrictive way and makes it possible to illustrate a principle of a non-reversible current and non-reversible voltage realization.

Figures 7 and 8 show architectures equivalent to that of the . On the , the capacitor C2 is connected between the first terminal X and the third terminal Z of the converter and an equivalent capacitor C3 is connected between the terminals Y and Z of the power converter PC. Likewise, on the , capacitor C1 is connected between terminals X and Y of the power converter and an equivalent capacitor C3 is connected between terminals Y and Z. To create the two voltage sources V1, V2, it is thus possible to imagine different combinations connection of two or three capacitors, between terminals X, Y, Z of the power converter PC.

There shows a second reversible current and voltage architecture.

In this second architecture:

• The first voltage source V ₁ includes a first capacitor C ₁ .
• The second voltage source V ₂ includes a second capacitor C ₂ .
• The first capacitor C ₁ is oriented so as to be able to create a positive or negative voltage in series with the first electrical conductor 1.
• The second capacitor C ₂ is oriented so as to be able to create a positive or negative voltage in series with the second electrical conductor 2.
• The switching means 31 comprise two switching arms connected in parallel between the second terminal Y and the third terminal Z of the converter. Each switching arm comprises two assemblies connected by the midpoint M and each formed, for example, of a transistor T ₁ , T ₂ , T ₃ , T ₄ (for example of the IGBT, IGCT, GTO, MOSFET type, etc.) and of a diode D ₁ , D ₂ , D ₃ , D ₄ in series. Depending on the transistor technology used, it is possible to dispense with diodes. The gate of each transistor is controlled by the control unit UC of the installation according to the appropriate control law.
• In the first switching arm:
  • The collector of each transistor T ₁ , T ₂ is connected to the midpoint M and their emitter is connected respectively to the second terminal Y and to the third terminal Z of the converter, via the diode D ₁ , D ₂ . Each diode is conductive oriented towards the corresponding terminal of the converter.
• In the second switching arm:
  • The collector of the first transistor T ₃ is connected to the second terminal Y of the converter and its emitter to the midpoint M ₂ , via diode D ₃ . The collector of the second transistor T ₄ is connected to the third terminal Z of the converter and its emitter is connected to the midpoint M, via the diode D ₄ . Each diode is conductively connected in the emitter to midpoint direction.
• The current source is formed by an inductance L, connected between the first terminal X of the converter and the midpoint M of the switching means.

This second architecture is to be considered in a non-limiting way and makes it possible to illustrate an embodiment provided with current and voltage reversibility. It can be used whatever the sign of the currents I ₁ and I ₂ , from the moment when I ₁ and I ₂ have the same sign. In all cases, the voltage V ₃ created by the converter between the two conductors can be positive or negative, thus making it possible to increase or decrease the current I ₁ caused to flow in the first electrical conductor.

There shows a third architecture, also reversible in current and in voltage. This architecture is equivalent to that of the second architecture, but produced in a more economical way, by using fewer electronic switches. In this structure:

• The first voltage source V ₁ includes a first capacitor C ₁ .
• The second voltage source V ₂ includes a second capacitor C ₂ .
• The first capacitor C ₁ is oriented so as to be able to create a positive voltage in series either with the first electrical conductor 1 or with the second electrical conductor 2.
• The second capacitor C ₂ is oriented so as to be able to create a negative voltage in series either with the first electrical conductor 1 or with the second electrical conductor 2.
• The switching means comprise a switching arm with two switches separated by the middle point. Each switch comprises a transistor T ₁ , T ₂ (for example of the IGBT, IGCT, GTO, MOSFET type, etc.) and a diode D ₁ , D ₂ in antiparallel. They also include several switches of the mechanical type (relay or contactor for example) arranged in a suitable manner to be able to configure the converter according to the current which is to be increased or decreased. It can be two groups of two switches. The first group comprises switches Sw ₁ , Sw ₂ and is connected on the one hand to the first voltage source and on the other hand to each of the two electrical conductors. The second group comprises switches Sw ₃ , Sw ₄ and is connected on the one hand to the second voltage source and on the other hand to each of the two electrical conductors. Each group makes it possible to selectively connect the voltage source considered in series with the first electrical conductor 1 or in series with the second electrical conductor 2.
• The current source is formed by an inductance L, connected between the first terminal of the converter and the midpoint M.

When the switches Sw1 and Sw4 are closed (Sw2 and Sw3 being open), the voltage V1 is inserted in series with the first electrical conductor 1 and the voltage V2 is inserted in series with the second electrical conductor 2. As in the case of the , the converter is then used to decrease the current in conductor 1 and to increase the current in conductor 2.

When switches Sw2 and Sw3 are closed (Sw1 and Sw4 being open), voltage V1 is inserted in series with second electrical conductor 2 and voltage V2 is inserted in series with first electrical conductor 1. Dually in the case of there , the power converter PC is used to increase the current in the first electrical conductor 1 and to decrease the current in the second electrical conductor 2.

There illustrates the advantages of inserting a converter in the installation to better distribute the currents. Apart from the converter, the installation has the same characteristics as those described above in connection with the . As a reminder, we thus have at the start:

• The total power P _T to be transmitted, equal to P+ΔP, being 1.6 GW.
• The first electrical conductor 1 with a section of 1200 mm² allowing it to transmit a nominal power P ₁ 'of 0.71 GW.

In this case, the second electrical conductor 2 has a section of 1900 mm², allowing it to transmit a nominal power P2' of 0.92 GW. In the example of the , the section was 2400 mm², allowing it to transmit a nominal power P2' of 1.05 GW.

The power converter PC is controlled to create a first voltage V ₁ in series with the first electrical conductor 1 and a second voltage V ₂ in series with the second electrical conductor 2, making it possible to modify the natural distribution of the current between the two electrical conductors . Thus, for the total power P _T of 1.6 GW, the first electrical conductor 1 will transmit a power of 0.68 GW with a current I ₁ of 1.07 kA and the second electrical conductor 2 will transmit a power of 0.92 GW with a current I ₂ of 1.43 kA.

Compared to the example of , it can be seen that the section of the second electrical conductor 2 could be reduced while maintaining the temperature of the conductors at a value less than or equal to the maximum admissible temperature (70° C. in this example). The cost of the second electrical conductor 2 is therefore reduced for the same total power P+ΔP transmitted.

According to a particular aspect of the invention, it turns out that the power converter can be especially useful when a fine distribution of the current must be operated, in particular when the power to be transmitted is close to the maximum value (P+ΔP) for which the installation is sized. Apart from that, it may be relevant not to use the PC converter, leaving the total current to be distributed naturally, according to the dimensioning of each of the two electrical conductors 1, 2. For this, with reference to the , the installation can incorporate a device for commissioning/decommissioning the PC power converter. This device may comprise a first switch Sw5 connected between the first main terminal A and the first connection terminal 1_1 of the first electrical conductor 1, in parallel with the first voltage source V1 formed between the first terminal X and second terminal Y of the converter PC , and a second switch Sw6 connected between the first main terminal A and the first connection terminal 2_1 of the second electrical conductor 2, in parallel with the second voltage source V2 formed between the first terminal X and the third terminal Z of the converter PC . When the two switches Sw5, Sw6 are closed, the converter PC is out of service, therefore inoperative by being bypassed (“bypass” in English), allowing the current to be distributed naturally in the two conductors 1, 2, according to their resistance respectively. In this realization of the , the PC converter is bypassed by default, so not used. It can be put into service and therefore inserted into the installation when the power transmitted by one of the two conductors reaches its nominal power (P1' for the first electrical conductor 1, P2' for the second electrical conductor 2). If the total power continues to increase, the converter PC is controlled to insert the appropriate voltages in series with each of the conductors 1, 2 and to distribute the current between the two conductors to rebalance the powers.

There shows an example of the control algorithm of the installation as represented on the , O corresponds to the "Yes" branch and N corresponds to the "No" branch). The steps are as follows:

• E0: Algorithm start-up step.
• E1: The converter is by default out of service in the installation, the switches Sw ₅ , Sw ₆ being in the closed state to bypass it. The control unit UC is responsible for measuring/estimating one or more physical parameters of the two electrical conductors 1, 2, among temperature, current, electrical power, etc.
• E2: The control unit UC performs tests on each of the measured/estimated parameters with respect to threshold values.
  • As long as none of these parameters exceeds the threshold value, the control unit executes step E1.
  • In the event that at least one of the monitored parameters takes a value greater than a threshold value or if an operator so decides, the control unit places the PC power converter in service and inserts it into the installation by opening the two switches Sw ₅ , Sw ₆ .
• E3: The control unit thus inserts the power converter PC between the two main terminals A, B. In its operating mode, the switching means 31 of the power converter PC are thus controlled by the control unit UC to fulfill one or more of the following objectives:
  • Maintain between the two conductors, for a given parameter, a constant ratio (for example a constant electric current ratio);
  • Maintain a difference given on a parameter, between the two conductors;
  • Control one or more of the parameters to maintain it at a reference level. This action can be implemented using a control loop responsible for determining the commands to be applied to the converter to maintain the measured or estimated parameter at the reference value;
• E4 When the PC power converter is no longer required (the monitored parameter falls below the threshold value) or on the decision of an operator, the PC power converter can again be put out of service.

Alternatively, the power converter could be inserted into the installation by default (the switches Sw ₅ , Sw ₆ open) with the switching means 31 controlled by UC so as not to add any voltage in series with the two conductors electrical.

It is understood from the foregoing that the solution of the invention makes it possible to upgrade a high voltage direct current installation, in a simple and reliable manner, providing the most accurate dimensioning, thus limiting the costs.

Claims (11)

Method of configuring a direct current high voltage installation, said installation comprising a first main terminal (A) and a second main terminal (B) between which is transmitted a so-called input/output electrical power, a first electrical conductor ( 1) which comprises a first connection terminal (1_1) and a second connection terminal (1_2), its second connection terminal (1_2) being connected to said second main terminal (B), said first electrical conductor (1) being dimensioned for transmitting a first rated electrical power (P₁'), said method being characterized in that it consists of:

• Add a second electrical conductor (2), which comprises a first connection terminal (2_1) and a second connection terminal (2_2), its second connection terminal (2_2) being connected to said second main terminal (B), said second electrical conductor (2) being sized to transmit a second nominal electrical power (P ₂ '),
• Add a power converter (PC) which comprises a first terminal (X), a second terminal (Y) and a third terminal (Z), said power converter being inserted into said installation so that its first terminal is connected to the first main terminal (A), its second terminal (Y) is connected to the first connection terminal (1_1) of the first electric conductor (1) and its third terminal is connected to the first connection terminal (2_1) of the second electric conductor (2), said power converter also comprising a first voltage source (V ₁ ) and a second voltage source (V ₂ ), and controllable means (3) for exchanging energy between the first voltage source ( V ₁ ) and the second voltage source (V ₂ ),
• Configuring a control unit (UC) of the power converter (PC) to make it capable of controlling the power converter (PC) with a view to adjusting the voltage supplied by said first voltage source (V ₁ ) in series with the first electrical conductor (1) and the voltage supplied by the second voltage source (V ₂ ) in series with said second electrical conductor and distributing said input/output electrical power in the first electrical conductor (1) and in the second electrical conductor (2), taking into account the first nominal electrical power (P ₁ ') that the first electrical conductor (1) is capable of transmitting and the second nominal electrical power (P ₂ ') that the second electrical conductor is capable of convey.

Method according to Claim 1, characterized in that the second electrical conductor is sized to transmit a second nominal electrical power (P ₂ ') distinct from the first nominal electrical power (P ₁ '). Method according to claim 1 or 2, characterized in that it consists of inserting a device for putting the power converter into operation/deactivating it, and controlling the said device for putting into service/deactivation of the power converter to insert the power converter between the two main terminals or bypass it. High voltage direct current installation which comprises a first main terminal (A) a second main terminal (B) between which is transmitted a so-called input/output electrical power, a first electrical conductor (1) which comprises a first connection terminal (1_1) and a second connection terminal (1_2), its second connection terminal (1_2) being connected to said second main terminal (B), said first electric conductor (1) being dimensioned to transmit a first nominal electric power (P₁'), said installation being characterized in that it is configured according to the method as defined in one of claims 1 to 3, integrating:

• A second electric conductor (2), which comprises a first connection terminal (2_1) and a second connection terminal (2_2), its second connection terminal (2_2) being connected to said second main terminal (B), said second conductor electrical (2) being sized to transmit a second nominal electrical power (P ₂ '),
• A power converter (PC) which comprises a first terminal (X), a second terminal (Y) and a third terminal (Z), said power converter being inserted in said installation so that its first terminal is connected to the first main terminal (A), its second terminal (Y) is connected to the first connection terminal (1_1) of the first electric conductor (1) and its third terminal is connected to the first connection terminal (2_1) of the second electric conductor ( 2), said power converter also comprising a first voltage source (V ₁ ) and a second voltage source (V ₂ ), and controllable means (3) for exchanging energy between the first voltage source (V ₁ ) and the second voltage source (V ₂ ),
• A control unit (UC) of said controllable means (3),
• Said controllable means (3) of the power converter (PC) being controlled by the control unit (UC) to adjust the voltage supplied by the said first voltage source (V ₁ ) in series with the first electrical conductor (1) and the voltage supplied by the second voltage source (V ₂ ) in series with the said second electrical conductor and distributing the said input/output electrical power in the first electrical conductor (1) and in the second electrical conductor (2), taking account of the first nominal electrical power (P ₁ ') that the first electrical conductor (1) is capable of transmitting and of the second nominal electrical power (P ₂ ') that the second electrical conductor is capable of transmitting.

Installation according to Claim 4, characterized in that the first voltage source (V ₁ ) is created between the first terminal (X) and the second terminal (Y) of the power converter (PC) and the second voltage source (V ₂ ) is created between the first terminal (X) and the third terminal (Z) of the power converter (PC). Installation according to Claim 5, characterized in that the said controllable means (3) comprise switching means (31) connected between the second terminal (Y) and the third terminal (Z) of the converter and a current source (30) connected between the first terminal (X) of the converter and a midpoint (M) of said switching means (31). Installation according to Claim 6, characterized in that the switching means (31) are chosen as non-reversible in current and non-reversible in voltage. Installation according to Claim 6, characterized in that the switching means (31) are chosen to be current reversible and voltage reversible. Installation according to one of Claims 6 to 8, characterized in that the current source (30) comprises an inductor (L). Installation according to one of Claims 4 to 9, characterized in that the first voltage source (V ₁ ) comprises a first capacitor (C ₁ ) and in that the second voltage source (V ₂ ) comprises a second capacitor ( _C2 ). Installation according to one of Claims 4 to 10, characterized in that it comprises a device for putting the power converter into operation/deactivation and a control unit (UC) configured to control said connection/disconnection device for to insert the power converter between the two main terminals or to bypass it.