EP4331101A1 - Non-isolated dc/dc voltage converter - Google Patents

Abstract

The invention relates to a voltage converter (10, 10') having first (12), second (14), third (16) and fourth (18) DC terminals and at least one arm (20, 30, 40) comprising exactly three electrical conversion modules (22, 32, 42, 24, 34, 44, 26, 36, 46), each comprising a chain of controllable submodules (SM) capable of assuming at least a first state in which a capacitor is inserted into the chain of submodules, the converter further comprising a first filter module (50) electrically connected between an intermediate point of the arm and said third DC terminal, and a second filter module (54) electrically connected between a second intermediate point of the arm and said second DC terminal.

Description

NON-INSULATED DC/DC VOLTAGE CONVERTER

Technical area

The present invention relates to the technical field of voltage converters making it possible to convert a first DC voltage into a second DC voltage. These voltage converters are also called DC/DC voltage converters. This type of converter is particularly suitable for installation in high-voltage direct current (HVDC) power supply installations.

DC/DC voltage converters allow the connection of a first portion of the DC power supply network with a second portion of the DC power supply network.

Prior technique

The voltage converters most commonly used in HVDC power supply installations are modular multilevel converters (MMC). These MMC converters offer excellent performance and numerous control possibilities. In addition, their modular structure makes it possible to build converters that can withstand very high voltages. A disadvantage of these converters is that they include very many components. In particular, if it is known to produce a DC/DC converter from two MMC converters interconnected in their AC parts by means of a transformer, the resulting DC/DC converter, called MMC “Front To Front” converter , comprises a very large number of components, is particularly bulky and has insufficient efficiency given the two conversion stages and the transformer.

A DC/DC converter is also known as disclosed in the publication G. J. Kish and P.W. Lehn, “Modeling Techniques for Dynamic and Steady-State Analysis of Modular Multilevel DC-DC Converters”. This converter makes it possible to connect a first portion of continuous electrical power supply network, having a bi-pole topology and comprising a first electrical pole and a second electrical pole, with a second portion of continuous electrical power supply network having a symmetrical monopole topology .

The voltage converter described in this document comprises first, second, third and fourth DC terminals. The first continuous terminal is configured to be connected to the first pole of the first network portion bi-pole topology DC power supply while the second DC terminal is configured to be connected to the second pole of the first portion of bi-pole topology DC power supply network. The converter further comprises an arm comprising first, second, third and fourth electrical conversion modules connected in cascade between the first DC terminal and the second DC terminal. These electrical conversion modules are each provided with chains of sub-modules.

A drawback of this converter is that it creates a coupling between the first and second poles of the first portion of the two-pole topology DC power supply network to which it is connected, given the currents flowing between the four modules. electrical conversion. Also, in the event of a fault or disturbance on the first or second pole of the first portion of the DC power supply network, this converter according to the prior art generates a disturbance on the other pole, which is nevertheless healthy. Consequently, in the event of a fault on only one of the two poles, all the power exchanges between the first and second portions of the continuous power supply network must be interrupted, for example by means of switches, and the voltage converter must be put on hold. The behavior in the event of faults of this converter is not satisfactory and does not correspond to what is generally expected of converters connected to a portion of the network with a bi-pole topology: it is expected that a fault on a pole does not disturb the other pole and that in the event of a fault, including internal to the converter, at least half of the nominal power of the first portion of the bi-pole topology supply network can be transferred without interruption. In other words, this converter does not offer redundancy which is detrimental.

Also, this converter is for bipolar interconnection. It comprises many components and is particularly bulky so that it is not suitable and sized to connect between them a first portion of power supply network of monopoly topology to a second portion of power supply network also of topology monopoly.

Disclosure of Invention

An object of the present invention is to propose a voltage converter remedying the aforementioned problems.

To do this, the invention relates to a voltage converter making it possible to convert a first DC voltage into a second DC voltage and vice versa, the voltage converter comprising: first and second DC terminals configured to be connected electrically to a first DC power supply network portion; third and fourth DC terminals configured to be electrically connected to a second DC power supply network portion; at least one arm comprising an upper point and a lower point between which it extends, the upper point being electrically connected to the first continuous terminal while the lower point is electrically connected to the fourth continuous terminal, the said at least one arm comprising a first electrical conversion module electrically connected between the upper point and a first intermediate point of the arm, a second electrical conversion module electrically connected between said first intermediate point and a second intermediate point of the arm, and a third electrical conversion module electrically connected between said second intermediate point and said lower point of the arm, the first intermediate point of the arm being electrically connected to the third DC terminal while the second intermediate point of the arm is connected to the second DC terminal, each of the first, second and third electrical conversion modules comprising nt a chain of sub-modules individually controllable by a control unit specific to each sub-module and each sub-module comprising a capacitor, the control unit of each sub-module being able to assume at least a first state in which the capacitor is inserted in the chain of sub-modules and a second state in which the capacitor is not inserted in said chain of sub-modules, at least one of the electrical conversion modules comprising an inductance connected in series with the chain of sub-modules of said electrical conversion module, said at least one arm comprising exactly three electrical conversion modules; a first filter module electrically connected between said first intermediate point of the arm and said third DC terminal, said first filter module being configured to limit the flow of an alternating electric current to said third DC terminal; and a second filter module electrically connected between said second intermediate point of the arm and said second DC terminal, said second filter module being configured to limit the flow of an alternating electric current to said second DC terminal.

Without departing from the scope of the invention, the first and second DC terminals are advantageously configured to be electrically connected to a first complete DC power supply network while the third and fourth DC terminals are configured to be electrically connected to a second full DC power supply network. Said DC power supply network portions may comprise one or more stations.

The first and second DC power supply network portions may have the same topology or different topologies. In a non-limiting manner, the first and the second portions of the DC power supply network may have a symmetrical monopoly, asymmetrical monopoly or bi-pole topology. In the latter case, the converter according to the invention is only connected to one of the two poles of said portion of the DC power supply network. The converter according to the invention therefore makes it possible to connect different topologies of network portions to one another and is therefore particularly versatile.

The first and third DC terminals are preferably configured to be electrically connected to a high voltage conductive line, also called a conductor. By high-voltage conductive line is meant a conductor configured to be placed at potentials with respect to ground of several tens of kilovolts (kV) or even several hundreds of kilovolts. The second DC terminal is preferably configured to be electrically connected to a low-voltage conductive line, for example a ground or a metal return. A low voltage conductive line is defined as opposed to a high voltage conductive line. In the case of a metallic return, a low-voltage line means a line configured to be placed at potentials with respect to earth of a few hundred volts or even a few kilovolts at most.

In a non-limiting way, the second continuous terminal can be connected to a conductor, itself connected to a ground or a metal return, in particular at a distance from a station.

Preferably, each of the first, second and third electrical conversion modules only comprises a chain of sub-modules. Preferably, each electrical conversion module comprises a single chain of sub-modules.

The first, second and third electrical conversion modules are connected, in cascade, in said at least one arm. It is understood that exactly three chains of sub-modules are connected in said at least one arm.

The first intermediate point of the arm is electrically connected to the third DC terminal via the first filter module. In other words, a bond electric extends between said third continuous terminal and the first intermediate point of the arm, in which the first filter module is connected. The second intermediate point of the arm is electrically connected to the second continuous terminal via the second filter module.

The control of the sub-modules in the various conversion modules makes it possible to impose the voltage at the terminals of the inductor or the voltages at the terminals of the inductances of the arm and therefore to control the rate and the amplitude of the currents circulating in the three converter modules. It is thus possible to impose an AC component and a DC component in these currents.

In addition to protecting the first and second portions of the DC power supply network against the circulation of an alternating current which could damage them, the first and second filtering modules allow the circulation of alternating currents in all the modules of electrical conversion of said at least one arm. This allows power exchanges between each of the arm's electrical conversion modules and ensures the energy balance of the converter.

The voltage converter according to the invention is particularly suitable for interconnecting a portion of a continuous power supply network with an asymmetric monopole topology and a portion of a continuous power supply network with a symmetrical monopole topology. Indeed, this converter is a non-isolated converter and eliminates the need for a transformer. It has reduced size, weight and manufacturing cost compared to a “Front To Front” MMC converter according to the prior art.

Unlike this "Front To Front" MMC converter in which all of the power to be transferred from one DC network portion to the other is transformed into AC power, the converter according to the invention allows a direct transfer from a part of the DC power from the first network portion to the second network portion without it being transformed into AC power. This reduces processing losses. The converter according to the invention further comprises a much smaller number of components and in particular an electrical conversion module, and therefore a chain of sub-modules, less than the converter described in the publication by GJ Kish and PW Lehn, which is sized for the connection of a bi-pole topology network to a monopoly network but is not intended to connect two monopoly topology networks, for which it is oversized and unsuitable. The converter according to the invention is therefore less bulky and suitable for the connection between two portions of continuous power supply network of monopoly topology, and in particular for the connection of a portion of network of symmetrical monopoly topology with a portion of network of monopoly topology asymmetric.

Alternatively, the voltage converter according to the invention also allows the connection between a portion of the continuous power supply network of bi-pole topology with a portion of the continuous power supply network of monopoly topology. In particular, it makes it possible to connect a first pole of a first portion of a continuous power supply network with a bi-pole topology with a second portion of a monopoly topology power supply network. A second converter according to the invention can also be used to connect a second pole of said first portion of continuous power supply network of bi-pole topology with said second portion of power supply network of monopoly topology. The invention therefore provides for the use of two voltage converters for connection to a bi-pole topology network portion, unlike the installation of the publication by G. J. Kish and P.W. Lehn, which provides for the use of a single converter for connect together a bi-pole topology network and a monopoly topology network. This converter according to the prior art performs a coupling between the poles of the two-pole network.

Conversely, the use of two physically separate voltage converters according to the invention makes it possible to maintain decoupling between the two poles of said first portion of network of bi-pole topology.

According to the invention, thanks to this decoupling, in the event of a disturbance on one of the poles of said first portion of the continuous power supply network of bi-pole topology, the other pole of this portion of the network is not impacted and can continue normal operation without interruption or disturbance. The redundancy of the continuous power supply network portion of bi-pole topology is maintained. In the event of a disturbance on one of the poles of the two-pole topology network portion, it is not necessary to interrupt the operation of the converter connected to the other pole of the two-pole network portion.

Furthermore, the symmetrical structure of the GJ Kish and PW Lehn converter only allows power exchanges between the first and second electrical conversion modules and between the third and fourth electrical conversion modules of this converter. On the contrary, the asymmetrical structure of the voltage converter according to the invention, comprising three electrical conversion modules, makes it possible to generate alternating currents circulating in each of the three electrical conversion modules and allowing energy exchanges between each of these electrical conversion modules. These energy exchanges ensure the energy balance of the voltage converter.

Preferably, the sub-modules of the chains of sub-modules of the first, second and third electrical conversion modules of said at least one arm have a half-bridge topology or a full-bridge topology. Without departing from the scope of the invention, an electrical conversion module may comprise only half-bridge sub-modules, only full-bridge sub-modules or a plurality of half-bridge sub-modules and a plurality of sub-modules. -full bridge modules.

Advantageously, the first electrical conversion module of said at least one arm comprises at least one sub-module having a full-bridge topology. Such a full-bridge sub-module is capable of generating negative voltages making it possible to interrupt the circulation of a fault current in said electrical conversion module.

Preferably, but in a non-limiting manner, in said at least one arm, only the first electrical conversion module comprises one or more full-bridge topology sub-modules.

Advantageously, the upper point of said at least one arm is electrically connected directly to the first continuous terminal.

Advantageously, the lower point of said at least one arm is electrically connected directly to the fourth continuous terminal.

In other words, no component, active or passive, is disposed between said upper point and the first continuous terminal or between said lower point and said fourth continuous terminal. The voltage converter is advantageously devoid of a switch disposed between said upper point and the first DC terminal or between said lower point and the fourth DC terminal, insofar as it makes it possible to overcome the problems of coupling of the converters according to the prior art and therefore the need to isolate a disturbed pole.

Preferably, each of the first and third electrical conversion modules of said at least one arm comprises an inductance connected in the arm, in series with the chain of sub-modules of the corresponding electrical conversion module. It is understood that a first inductor is arranged between the upper point and the first intermediate point of the arm and that a second inductor is arranged between the second intermediate point and the lower point of the arm. In a non-limiting manner, the second electrical conversion module may comprise an inductance connected in the arm, in series with the chain of sub-modules of said second electrical conversion module.

Advantageously, the first filtering module comprises at least one passive component, for example an inductor. By passive component is meant a non-controllable component. Such a passive component does not produce energy, voltage or current. In a non-limiting way, it can also be a resistor or a capacitor.

In a non-limiting manner, the first filtering module may comprise only passive components, so that it forms a passive filtering module.

Preferably, the second filtering module comprises at least one passive component.

Preferably, but in a non-limiting way, the first filtering module comprises at least one active component, for example a transistor, so that the first filtering module is active. By active component is meant a controllable component whose change of state can be controlled, for example the passage from a closed/blocked state to an open/conducting state. Such an active component is preferably capable of generating a controlled voltage or current. In a non-limiting way, it can be a switch, a semiconductor, such as a transistor or even a sub-module comprising at least one semiconductor.

Advantageously, the second filtering module comprises at least one active component.

Preferably, the converter comprises a plurality of arms connected in parallel with respect to each other, each arm comprising an upper point and a lower point between which it extends, the upper point of each of the arms being electrically connected to the first continuous terminal while the lower point of each of the arms is electrically connected to the fourth continuous terminal, each arm comprising a first electrical conversion module electrically connected between the upper point and a first intermediate point of said arm, a second electrical conversion module electrically connected between said first intermediate point and a second intermediate point of said arm, and a third electrical conversion module electrically connected between said second intermediate point and said lower point of said arm, the first intermediate point of each of the arms being electrically connected to the third DC terminal while the e second intermediate point of each of the arms is connected to the second DC terminal, said first filter module being electrically connected between said first intermediate points of the arms and said third DC terminal, said second filter module being electrically connected between said second intermediate points of the arms and said second DC terminal, each of the first, second and third electrical conversion modules of each of the arms comprising a chain of controllable sub-modules, each arm comprising exactly three electrical conversion modules.

The upper points of each of the arms are interconnected and form the same electrical node. Similarly, the lower points of each of the arms are interconnected and form the same electrical node.

The first intermediate points of each of the arms are electrically connected to the third DC terminal via the first filter module. The second intermediate points of each of the arms are electrically connected to the second DC terminal via the second filter module.

The sub-modules of the electrical conversion modules of each of the arms are individually controllable by a control unit specific to each sub-module and each sub-module comprises a capacitor, the control unit of each sub-module being able to take at least a first state in which the capacitor is inserted in the chain of sub-modules and a second state in which the capacitor is not inserted in said chain of sub-modules.

The voltage converter preferably comprises at least three arms connected in parallel, more preferably exactly three arms.

According to a particularly advantageous aspect of the invention, the converter further comprises a control module configured to control the sub-modules of the first, second and third electrical conversion modules so as to generate first, second and third alternating currents circulating respectively in the chains of sub-modules of said first, second and third electrical conversion modules, these alternating currents generating energy exchanges between the first and second electrical conversion modules, between the first and third electrical conversion modules as well as between the second and third electrical conversion modules. These exchanges are made possible by the asymmetrical structure of the converter according to the invention. These energy exchanges ensure the energy balance of the voltage converter.

The invention also relates to a high voltage direct current transmission installation comprising a first portion of direct current power supply network, a second portion of direct power supply network and at least one first voltage converter as described previously, said first voltage converter being configured to electrically connect said first and second DC power supply network portions to one another.

Preferably, the first continuous electrical power supply network portion has a first topology, for example an asymmetrical monopole or bi-pole type topology, while the second continuous electrical power supply network portion has a second topology, different from the first topology, for example a symmetric monopoly type topology. The voltage converter according to the invention is therefore particularly versatile and allows heterogeneous interconnections. In a non-limiting manner, the first portion of the continuous power supply network could also be of symmetrical monopoly topology.

According to a particularly advantageous aspect of the invention, the first portion of the DC power supply network comprises at least one first high-voltage conductive line electrically connected to the first DC terminal of the first voltage converter and a low-voltage return line connected electrically to the second DC terminal of the first converter, and the second portion of DC power supply network comprises a first high-voltage conductive line electrically connected to the third DC terminal of the first voltage converter and a second high-voltage conductive line electrically connected to the fourth DC terminal of the first voltage converter.

In this configuration, the first portion of the DC power supply network can be of asymmetric monopoly or bi-pole topology. In this second case, the voltage converter is connected to a first pole of the first network portion. The second portion of the DC power supply network is of symmetrical monopole topology.

The high-voltage conductive lines of the first and second network portions are conductors. Without limitation, the return line can be a ground line or a metal return.

Advantageously, the first portion of the DC power supply network further comprises a second high voltage conductive line, the installation further comprising a second voltage converter as described above, the first DC terminal of said second voltage converter being electrically connected to said second high-voltage conductive line of the first DC power supply network portion, the second DC terminal of the second voltage converter being electrically connected to the low-voltage return line of the first portion of DC power supply network, the third DC terminal of the second converter being electrically connected to the second high-voltage conductor line of the second portion of DC power supply network, and the fourth DC terminal of the second voltage converter being electrically connected to the first high-voltage conductive line of the second portion of the DC power supply network.

In this embodiment, it is understood that the first DC power supply network portion is of bi-pole topology, the second voltage converter being connected to a second pole of said first network portion. The first and second voltage converters are physically separate.

The two converters operate independently of each other and make it possible to maintain decoupling between the poles of the first portion of the two-pole topology continuous power supply network. Also, a disturbance on one pole does not cause any disturbance on the other pole, which can continue its normal operation. The redundancy of the bipolar system is maintained.

The sub-modules of the second voltage converter are connected according to a suitable polarity. Preferably, the sub-modules of the second converter are connected according to an inverted polarity with respect to the sub-modules of the first voltage converter.

The invention also relates to a method for controlling a voltage converter as described previously, in which the sub-modules of the first, second and third electrical conversion modules are controlled so as to generate first, second and third currents alternating currents circulating respectively in said first, second and third electric conversion modules, these alternating currents generating energy exchanges between the first and second electric conversion modules, between the first and third electric conversion modules as well as between the second and third electrical conversion modules.

Brief description of the drawings

The invention will be better understood on reading the following description of embodiments of the invention given by way of non-limiting examples, with reference to the appended drawings, in which:

[Fig. 1] Figure 1 illustrates a voltage converter according to the invention;

[Fig. 2] Figure 2 illustrates a half-bridge topology sub-module of the voltage converter of Figure 1; [Fig. 3] Figure 3 illustrates a full-bridge topology sub-module of the voltage converter of Figure 1;

[Fig. 4] Figure 4 illustrates a first embodiment of an HVDC installation according to the invention; and

[Fig. 5] Figure 5 illustrates a second embodiment of an HVDC installation according to the invention.

Description of embodiments

The invention relates to a DC/DC voltage converter, in particular a voltage converter particularly suitable for being installed in an HVDC installation. Such a voltage converter is configured to convert a first DC voltage U1 into a second DC voltage U2 and vice versa.

FIG. 1 illustrates such a voltage converter 10 according to the invention, making it possible to connect a first portion of DC power supply network with a second portion of DC power supply network having the same topology or different topologies.

This voltage converter 10 comprises a first DC terminal 12, a second DC terminal 14, a third DC terminal 16 and a fourth DC terminal 18. The first and second DC terminals 12,14 are configured to be electrically connected to a first portion of DC power supply network, while the third and fourth DC terminals 16,18 are configured to be electrically connected to a second portion of DC power supply network. The first DC voltage U1 is shown between the first and second DC terminals, the second DC voltage U2 is shown between the third and fourth DC terminals and results from the sum of the voltage +U3 shown between the third DC terminal and a ground and of the -U4 voltage shown between the fourth DC terminal and this ground. The voltages U3 and U4 are equal in the case of a connection to a network of the symmetrical monopole type.

According to the invention, the voltage converter 10 further comprises a first arm 20 comprising an upper point 20a and a lower point 20b between which it extends. In a non-limiting manner, the voltage converter further comprises a second arm 30 comprising an upper point 30a and a lower point 30b between which it extends and a third arm 40 comprising an upper point 40a and a lower point 40b between which it extends.

The upper points 20a, 30a, 40a of the three arms 20,30,40 are interconnected and form the same electrical node. Each of the upper points is connected electrically directly to the first continuous terminal 12. Similarly, the lower points 20b, 30b, 40b of the three arms 20,30,40 are interconnected and form the same electrical node. Each of the lower points is electrically connected directly to the fourth continuous terminal 18. The three arms 20,30,40 are therefore connected in parallel with respect to each other between the first continuous terminal 12 and the fourth continuous terminal 18.

According to the invention, each of the arms 20,30,40 of the voltage converter comprises exactly three electrical conversion modules. The first arm comprises a first electrical conversion module 22 electrically connected between the upper point 20a and a first intermediate point 20c of the first arm. It also comprises a second electrical conversion module 24 electrically connected between said first intermediate point 20c and a second intermediate point 20d of the first arm 20, and a third electrical conversion module 26 electrically connected between said second intermediate point 20d and said lower point 20b of the first arm.

Similarly, the second and third arms 30,40 each comprise a first electrical conversion module 32,42 electrically connected between the upper point 30a, 40a and a first intermediate point 30c, 40c of the corresponding arm 30,40. They also each comprise a second electrical conversion module 34,44 electrically connected between said first intermediate point 30c, 40c and a second intermediate point 30d,40d of the corresponding arm 30,40, and a third electrical conversion module 36,46 electrically connected between said second intermediate point 30d, 40d and said lower point 30b, 40b of the corresponding arm 30,40.

Each of the first, second and third electrical conversion modules 22,24,26,32,34,36,42,44,46 of each of the arms 20,30,40 comprises a chain of sub-modules SM. These SM sub-modules are connected in series to each other in the corresponding arm. The SM sub-modules are individually controllable according to a desired sequence in order to modify the voltage at the terminals of each of the chains of sub-modules. Each chain of sub-modules SM can be modeled by a controllable voltage source able to generate a voltage at its terminals depending on the number of capacitors inserted and placed in series in said chain of sub-modules.

Each of the first, second and third electrical conversion modules 22,24,26,32,34,36,42,44,46 of each of the arms 20,30,40 comprises only one chain of sub-modules SM.

In this non-limiting example, the second and third electrical conversion modules of the first, second and third arms 20,30,40 do not include only half-bridge topology sub-modules, or “Half-bridge” in English.

Figure 2 illustrates an SM submodule having a half-bridge topology. This sub-module SM comprises a capacitor CSM, and a control unit T1, T2 making it possible to individually control the sub-module SM. In a non-limiting manner, the control unit T1, T2 comprises a first electronic switching element T1 such as an insulated gate bipolar transistor ("IGBT: Insulated Gate Bipolar Transistor" in English) connected in series with the capacitor CSM - This first switching element T1 and this capacitor CSM are mounted in parallel with a second electronic switching element T2, also an insulated gate bipolar transistor (IGBT). This second electronic switching element T2 is connected between the input and output terminals of the sub-module SM. The first and second switching elements T1 and T2 are both associated with an antiparallel diode D represented in FIG. 2. In a non-limiting manner, the switching elements could be of the IGBTs, MOSFETs or IGCTs type.

The control device T1, T2 of each sub-module SM can assume a first state in which the capacitor CSM is inserted in the corresponding chain of sub-modules and a second state in which the capacitor is not inserted in said chain. of sub-modules. In a non-limiting way, the control member T1, T2 can also assume a non-controlled state in which the first and second switching elements T1, T2 are open so that the insertion of the capacitor CSM depends on the sign of the current circulating in the corresponding half-arm, given the anti-parallel diodes.

In this non-limiting example, the first electrical conversion modules 22,32,42 of the first, second and third arms 20,30,40 each comprise a plurality of full-bridge topology sub-modules, or "Full-bridge" in English language. Figure 3 illustrates such a full-bridge topology sub-module. In this topology, the sub-module comprises four switching elements T'1, T'2, T'3, T'4, each being associated in parallel with an antiparallel diode D.

Without departing from the scope of the invention, each of the electrical conversion modules of the voltage converter 10 could comprise one or more full-bridge topology sub-modules SM.

Each of the electrical conversion modules 22,24,26,32,34,36,42,44,46 further comprises an inductance 27 connected in series with the chain of sub-modules SM of the corresponding electrical conversion module. the control of the voltages generated by the chains of sub-modules SM makes it possible to impose the voltages at the terminals of the inductors 27 and therefore to control the currents flowing in the arms 20,30,40 of the voltage converter 10. In a nonlimiting manner, the second electrical conversion modules 24,34,44 of the first, second and third arms 20,30,40 could be devoid of such an inductor 27.

Furthermore, the voltage converter 10 comprises a first filter module 50 connected between the first intermediate points 20c, 30c, 40c of the first, second and third arms 20,30,40 and the third DC terminal 16. In other words , the first intermediate points 20c, 30c, 40c of the first, second and third arms 20,30,40 are connected to the third DC terminal 16 via said first filter module 50. The first filter module 50 is configured to limit the flow of an alternating electric current to said third DC terminal 16.

In this non-limiting example, the first filter module 50 comprises three inductors 52, which are passive components, each being connected between the first intermediate point 20c, 30c, 40c of one of the arms and the third DC terminal. The first filtering module is therefore passive.

The voltage converter 10 also includes a second filter module 54 connected between the second intermediate points 20d, 30d, 40d of the first, second and third arms 20, 30, 40 and the second continuous terminal 14. In other words, the second intermediate points 20d,30d,40d of the first, second and third arms 20,30,40 are connected to the second continuous terminal 14 via said second filter module 54. The second filter module 54 is configured to limit the circulation an alternating electric current to said second DC terminal 14.

In this non-limiting example, the second filter module 54 comprises three inductors 56, which are passive components, each being connected between the second intermediate point 20d, 30d, 40d of one of the arms and the second continuous terminal 14. The second filtering module is therefore passive.

The voltage converter 10 according to the invention also has an asymmetrical structure in which each arm 20,30,40 comprises three electrical conversion modules. This makes it possible to generate alternating currents circulating in each of the three electrical conversion modules of each of the arms. These currents generate energy exchanges between each of the three electrical conversion modules.

In particular, in each of the arms 20,30,40 the sub-modules can be controlled so as to generate first, second and third currents AC circulating respectively in said first 22,32,42, second 24,34,44, and third 26,36,46 electrical conversion modules of each of the arms. These alternating currents generate, in each of the arms, energy exchanges between all the electrical conversion modules and more precisely between the first 22,32,42 and second 24,34,44 electrical conversion modules, between the first 22, 32,42 and third 26,36,46 electrical conversion modules as well as between the second 24,34,44 and third 26,36,46 electrical conversion modules. These energy exchanges ensure the energy balance of the voltage converter.

In Figure 1, we see that the voltage converter 10 includes a control module 80 configured to control the SM sub-modules of the first 22,32,42, second 24,34,44, and third 26,36,46 modules electrical conversion, in particular to generate said first, second and third alternating currents. This control module also makes it possible to generate direct currents allowing power exchanges between the converter and the portions of the direct electrical power supply network.

FIG. 4 illustrates a first embodiment of an installation 8 according to the invention, in this case an installation for transporting high-voltage direct current (HVDC), comprising a voltage converter 10 connecting between them a first portion of continuous power supply network 60 of asymmetrical monopole topology and a second portion of continuous power supply network 70 of symmetrical monopole topology.

The first portion of DC power supply network 60 comprises a first station 62 formed by an AC/DC voltage converter, and a second station 64, formed by a second AC/DC voltage converter. These first and second stations 62,64 are electrically interconnected by a first high-voltage conductive line 66, also called a conductor, and by a low-voltage return line 68, here a metallic return. The first DC terminal 12 of the DC/DC voltage converter 10 is connected to the first high-voltage conductive line 66 while the second DC terminal 14 is connected to the first low-voltage return line 68.

The second portion of DC power supply network 70 comprises a first station 73 formed by an AC/DC voltage converter, and a second station 74, formed by a second AC/DC voltage converter. These first and second stations 73,74 are electrically interconnected by a first high-voltage conductive line 76, forming a conductor, and by a second high-voltage conductive line 78, also forming a conductor. The third DC terminal 16 of the DC/DC voltage converter 10 is connected to the first high-voltage conductive line 76 of this second network portion 70 while the fourth DC terminal 18 is connected to the second high-voltage conductive line 78.

As illustrated in this figure 4, the voltage converter 10 according to the invention is particularly suitable for connecting together two portions of a monopoly topology continuous power supply network and in particular a portion of asymmetrical monopoly topology network and a portion monopoly symmetric topology network. Indeed, this voltage converter 10 is a non-isolated converter and makes it possible to dispense with the use of a transformer. It therefore has reduced bulk, weight and manufacturing cost compared to a “Front To Front” MMC converter according to the prior art, while ensuring optimum electrical conversion.

In Figure 4, the square-shaped elements connected to the AC part of the stations represent AC circuit breakers.

As illustrated in FIG. 5, the voltage converter 10 according to the invention is also suitable for interconnecting a portion of the power supply network with a bi-pole topology and a portion of the power supply network with a monopoly topology. , here symmetric monopoly.

Figure 5 illustrates a second embodiment of an 8' FIVDC installation according to the invention. In this embodiment, the first portion of DC power supply network 60' comprises a first station 62', a second station 64', a third station 63' and a fourth station 65', each formed of an AC converter /DC. The first and second stations 62', 64' are interconnected by a first high-voltage conductive line 66' and by a low-voltage return line 68', in this case a metallic return line. The third and fourth stations 63', 65' are interconnected by a second high-voltage conductive line 72' and by said low-voltage return line 68'. The second portion of DC power supply network 70 is similar to that of the embodiment of Figure 4.

In this non-limiting embodiment, the installation 8′ comprises a first DC/DC voltage converter 10, such as that illustrated in FIG. 1 and further comprising first, second, third and fourth DC terminals 12,14,16 ,18. The installation 8' further comprises a second voltage converter 10', such as that illustrated in FIG. 1 and substantially similar to the first voltage converter 10. This second voltage converter 10' also comprises first, second, third and fourth continuous terminals 12', 14', 16', 18'. The sub-modules of the second converter voltage 10 'are however connected according to an inverted polarity with respect to the sub-modules of the first voltage converter 10.

The first DC terminal 12 of the first voltage converter 10 is connected to the first high-voltage conductive line 66' of the first DC power supply network portion 60' while the second DC terminal 14 is connected to the return line low-voltage 68 'of this first network portion. The third DC terminal 16 of the first DC/DC voltage converter 10 is connected to the first high-voltage conductive line 76 of the second network portion 70 while the fourth DC terminal 18 is connected to the second high-voltage conductive line 78 of this second network portion 70.

The first DC terminal 12' of the second voltage converter 10' is connected to the second high-voltage conductive line 72' of the first DC power supply network portion 60' while the second DC terminal 14' of this second converter 10' is connected to the low-voltage return line 68' of this first network portion. The third DC terminal 16' of the second DC/DC voltage converter 10' is connected to the second high-voltage conductive line 78 of the second network portion 70 while the fourth DC terminal 18' of the second voltage converter 10' is connected to the first high-voltage conductive line 78 of this second network portion 70.

In other words, the first voltage converter 10 is electrically connected to a first pole of the first portion of continuous power supply network of bi-pole topology 60', while the second voltage converter 10' is electrically connected at the second pole of this first network portion.

In this 8' installation according to the invention, the two 10,10' voltage converters are physically separate and independent of each other. An advantage is to maintain the decoupling between the two poles of the first portion of the DC power supply network 60′ so that a disturbance on one of these poles does not impact the other pole. In this situation, the operation of the converter connected to the faulty pole can be interrupted while the converter connected to the healthy pole continues its normal operation. Thanks to the invention, the redundancy of the bipolar system is therefore preserved, unlike the installation of the publication by G. J. Kish and P.W. Lehn, which admittedly only uses a single converter but generates a coupling between the poles of the two-pole network to which it is connected, causing the complete shutdown of the converter and therefore of the power conversion when only one of its poles is disturbed.

Claims

Claims

1. Voltage converter (10,100 making it possible to convert a first DC voltage (Ul) into a second DC voltage (U2) and vice versa, the voltage converter comprising: first (12) and second (14) DC terminals configured to be connected electrically to a first DC power supply network portion (60,600); third (16) and fourth (18) DC terminals configured to be electrically connected to a second DC power supply network portion (70); at least one arm (20,30,40) comprising an upper point (20a, 30a, 40a) and a lower point (20b, 30b, 40b) between which it extends, the upper point being electrically connected to the first continuous terminal while the lower point is electrically connected to the fourth continuous terminal, said at least one arm comprising a first electrical conversion module (22,32,42) electrically connected between the upper point and a first intermediate point ire (20c, 30c, 40c) of the arm, a second electrical conversion module (24,34,44) electrically connected between said first intermediate point and a second intermediate point (20d,30d,40d) of the arm, and a third module converter (26,36,46) electrically connected between said second intermediate point and said lower point of the arm, the first intermediate point of the arm being electrically connected to the third DC terminal while the second intermediate point of the arm is connected to the second terminal continuous, each of the first, second and third electrical conversion modules comprising a chain of sub-modules (SM) individually controllable by a control unit (T1, T2) specific to each sub-module and each sub-module comprising a capacitor ( CSM), the control unit of each sub-module being able to take at least a first state in which the capacitor is inserted in the chain of sub-modules and a second state da ns wherein the capacitor is not inserted in said chain of sub-modules, at least one of the electrical conversion modules comprising an inductance (27) connected in series with the chain of sub-modules of said electrical conversion module, said at least one arm comprising exactly three electrical conversion modules; a first filter module (50) electrically connected between said first intermediate point of the arm and said third terminal dc, said first filter module being configured to limit the flow of an alternating electric current to said third dc terminal; and a second filter module (54) electrically connected between said second midpoint of the arm and said second DC terminal, said second filter module being configured to limit the flow of alternating electrical current to said second DC terminal.

2. Voltage converter according to claim 1, in which the sub-modules (SM) of the chains of sub-modules of the first (22,32,42), second (24,34,44) and third (26,36, 46) electrical conversion modules of said at least one arm have a half-bridge topology or a full-bridge topology.

3. Voltage converter according to claim 2, in which the first electrical conversion module (22,32,42) of said at least one arm (20,30,40) comprises at least one sub-module (SM) having a topology in full bridge.

4. Voltage converter according to any one of claims 1 to 3, wherein the upper point (20a, 30a, 40a) of said at least one arm (20,30,40) is electrically connected directly to the first DC terminal (12 ).

5. Voltage converter according to any one of claims 1 to 4, wherein the lower point (20b, 30b, 40b) of said at least one arm (20,30,40) is electrically connected directly to the fourth DC terminal (18 ).

6. Voltage converter according to any one of claims 1 to 5, wherein each of the first (22,32,42) and third (26,36,46) electrical conversion modules of said at least one arm comprises an inductance ( 27) connected in the arm (20,30,40), in series with the chain of sub-modules (SM) of the corresponding electrical conversion module.

7. Voltage converter according to any one of claims 1 to 6, wherein the first filter module (50) comprises at least one passive component, for example an inductor (52).

8. Voltage converter according to any one of claims 1 to 7, wherein the first filter module (50) comprises at least one active component, for example a transistor.

9. Voltage converter according to any one of claims 1 to 8, comprising a plurality of arms (20,30,40) connected in parallel with respect to each other, each arm comprising an upper point (20a, 30a, 40a ) and a lower point (20b, 30b, 40b) between which it extends, the upper point of each of the arms being electrically connected to the first continuous terminal (12) while the lower point of each of the arms is electrically connected to the fourth continuous terminal (18), each arm comprising a first electrical conversion module (22,32,42) electrically connected between the upper point and a first intermediate point (20c, 30c, 40c) of said arm, a second electrical conversion module ( 24,34,44) electrically connected between said first intermediate point and a second intermediate point (20d,30d,40d) of said arm, and a third electrical conversion module (26,36,46) electrically connected between said second intermediate point and t said lower point of said arm, the first intermediate point of each of the arms being electrically connected to the third DC terminal (16) while the second intermediate point of each of the arms is connected to the second DC terminal (14), said first filter module being electrically connected between said first intermediate points of the arms and said third continuous terminal (16), said second filter module being electrically connected between said second intermediate points of the arms and said second continuous terminal (14), each of the first, second and third electrical conversion modules of each of the arms comprising a chain of controllable sub-modules (SM), each arm comprising exactly three electrical conversion modules.

10. Voltage converter according to any one of claims 1 to 9, further comprising a control module (80) configured to control the sub-modules of the first (22,32,42), second (24,34,44 ), and third (26,36,46) electrical conversion modules so as to generate first, second and third alternating currents circulating respectively in the chains of sub-modules of said first, second and third electrical conversion modules, these alternating currents generating exchanges of energy between the first and second electrical conversion modules, between the first and third electrical conversion modules as well as between the second and third electrical conversion modules.

11. Installation (8,8 ') for transporting high voltage direct current comprising a first portion of direct power supply network (60,60'), a second portion of direct power supply network (70) and at least a first voltage converter (10,10') according to any one of claims 1 to 10, said first voltage converter being configured to electrically connect said first and second DC power supply network portions to each other.

12. Installation according to claim 11, in which the first portion of the DC power supply network (60,60') has a first topology, for example a topology of the asymmetrical monopole or bi-pole type, while the second portion of DC power supply network (70) has a second topology, different from the first topology, for example a symmetrical monopole type topology.

13. Installation according to claim 12, in which the first portion of DC power supply network (60,60') comprises at least one first high-voltage conductive line (66,66') electrically connected to the first DC terminal (12 ) of the first voltage converter (10) and a low-voltage return line (68,68') electrically connected to the second DC terminal (14) of the first converter, and in which the second DC power supply network portion ( 70) comprises a first high voltage conductive line (76) electrically connected to the third DC terminal (16) of the first voltage converter and a second high voltage conductive line (78) electrically connected to the fourth DC terminal (18) of the first voltage converter Of voltage.

14. Installation (8 ') according to claim 13, wherein the first portion of DC power supply network (60') further comprises a second high voltage conductive line (72'), the installation further comprising a second voltage converter (10') according to any one of claims 1 to 10, the first DC terminal (12') of said second voltage converter being electrically connected to said second high-voltage conductive line of the first network portion of feed direct current, the second direct current terminal (14') of the second voltage converter being electrically connected to the low voltage return line (68') of the first portion of direct current power supply network, the third direct current terminal (16') of the second converter being electrically connected to the second high-voltage conductive line (78) of the second portion of DC power supply network (70), and the fourth DC terminal (18') of the second voltage converter being electrically connected to the first high-voltage conductive line (76) of the second portion of the DC power supply network.

15. Method for controlling a voltage converter (10,10') according to any one of claims 1 to 10, in which the sub-modules (SM) of the first (22,32,42), second (24,34,44) and third (26,36,46) electrical conversion modules so as to generate first, second and third alternating currents flowing respectively in said first, second and third electrical conversion modules, these alternating currents generating energy exchanges between the first and second electrical conversion modules, between the first and third electrical conversion modules as well as between the second and third electrical conversion modules.