Method for controlling a series electrical distribution system and associated series electrical distribution system

By connecting conversion modules in series with a power supply and regulating DC voltage and apparent power, the method addresses inefficiencies in data center architecture, reducing costs and size while ensuring stable power delivery.

FR3161989B1Active Publication Date: 2026-06-05SCHNEIDER ELECTRIC IND SAS

Patent Information

Authority / Receiving Office
FR · FR
Patent Type
Patents
Current Assignee / Owner
SCHNEIDER ELECTRIC IND SAS
Filing Date
2024-05-02
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

The current architecture of data centers is not adapted to the increase in computing power of equipment due to high manufacturing costs and size, primarily because transformers and electrical connections are sized for significant electrical power consumption, which is inefficient and costly.

Method used

A method for controlling an electrical distribution system where conversion modules are connected in series with a power supply, converting medium voltage to low voltage, and a control method regulates DC voltage and apparent power to maintain balance, eliminating the need for intermediate low-voltage distribution networks.

Benefits of technology

This approach reduces material costs, particularly copper requirements, and improves compactness by simplifying the electrical infrastructure, ensuring stable power delivery and operational balance.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

The present invention relates to a method for controlling an electrical distribution system comprising a power supply delivering a medium-voltage alternating current, electrical loads, and a load-conversion module. The input terminals of all modules are connected in series with each other and with the power supply. Each module includes a converter delivering a low-voltage direct current to its electrical load from the medium voltage. The method comprises, for each module, adjusting the active power delivered by the module according to the active operating power of its electrical load and maintaining a constant apparent power of the module by regulating the amplitude and phase shift of the voltage across its terminals, based on the active power delivered by the module to its electrical load, the voltage and current delivered by the power supply to the modules, and the number of modules.Figure for the abridged version: 1.
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Description

Title of the invention: Method for controlling a series electrical distribution system and associated series electrical distribution system

[0001] The present invention relates to a method for controlling an electrical distribution system, in particular a data processing center, and an associated electrical distribution system.

[0002] A data center, also known as a data processing center or IT center, is a facility that houses various pieces of equipment belonging to an information system, such as mainframe computers, servers, data storage devices, network equipment, and / or telecommunications equipment. This equipment generates electrical loads and is arranged in racks (i.e., cabinets of standardized dimensions). A rack typically comprises one or more pieces of equipment, generally arranged in drawers or enclosures of standardized dimensions.

[0003] The racks in a data center are powered by a power supply, and the equipment mounted in a rack typically operates at low voltage, i.e., at a voltage between 48 V and 400 V. The equipment in a data center is electrically connected in parallel to the power supply, which then delivers a low-voltage electrical current to each of the racks. Given the high electrical power consumed by a data center, the power supply itself is fed by a medium-voltage electrical network, i.e., at a voltage between 10 kV and 35 kV, so one or more transformers are required to transform this medium voltage into the low voltage that powers the racks.

[0004] The increase in computing power of equipment, driven in particular by the development of artificial intelligence, leads to an increase in the electrical power required to power this equipment. For example, a server rack can consume up to 100 kW of electrical power. Therefore, transformers and electrical connections linking the power supply to the equipment, most often made of copper, must be sized to handle significant electrical power (very high current at low voltage), which significantly increases their manufacturing cost and size.

[0005] In other words, the current architecture of data centers is not adapted to the increase in the computing power of the equipment because of an installation cost and a size that is too high.

[0006] It is this drawback that the invention intends to remedy, by proposing a method for controlling an electrical distribution system, in particular a data processing center, and by proposing a corresponding improved electrical distribution system architecture, the manufacturing cost and size of which are reduced.

[0007] To this end, the invention relates to a method for controlling an electrical distribution system, the electrical distribution system comprising: - a power supply device, configured to deliver a first current, which is a single-phase alternating current, associated with a first voltage, which is a single-phase alternating voltage between 10 kV and 35 kV, - a plurality of electrical loads, for example a data server, - a plurality of conversion modules, the conversion modules being respectively associated with electrical charges, • each conversion module comprising input terminals and output terminals, • the input terminals of all the conversion modules being connected in series with each other and with the power supply device, the first current thus flowing between the input terminals of all the conversion modules, the first voltage thus being applied to all the conversion modules, • the output terminals of each conversion module being connected to the electrical load associated with the conversion module, • each conversion module comprising a converter, connected to the output terminals of the conversion module and configured to deliver to the associated electrical load a DC voltage between 48 V and 400 V and a DC current, from the AC voltage at the input terminals of the conversion module and the AC current flowing between the input terminals of the conversion module, thus delivering an active power supplying the associated electrical load.

[0008] The control method comprises, for each conversion module: - regulate the DC voltage delivered by the conversion module to the associated electrical load, to maintain it at a constant value, based on an active operating power value imposed by the electrical load, and - maintain an apparent power of the conversion module equal to a target value, so that the apparent powers of all conversion modules are equal, by regulating the amplitude of the alternating voltage at the input terminals of the conversion module and the phase shift between the alternating voltage at the input terminals of the conversion module and the alternating current flowing between the input terminals of the conversion module, based on: • of the active power delivered by the conversion module to the associated electrical load, • of the alternating voltage and alternating current delivered by the power supply device to the plurality of conversion modules, and • the number of conversion modules.

[0009] Thanks to the invention, all the conversion modules are connected in series to the power supply that delivers a medium voltage, and the medium-voltage to low-voltage conversion is carried out by the conversion modules to power the electrical loads. Therefore, an intermediate low-voltage distribution network between the power supply and the electrical loads is no longer necessary, simplifying the electrical infrastructure compared to an architecture in which all the electrical loads are connected in parallel to a low-voltage power supply. The material cost of the electrical distribution system, and more specifically the amount of copper required for its construction, is thus reduced, and its compactness is improved.

[0010] This architecture, in which all the conversion modules are connected in series to the power supply and powered by medium voltage, is made possible by the control method of the invention. In this method, each conversion module is controlled to maintain an apparent power equal to a target value, so that the apparent power of all the conversion modules is equal. This allows the power supply to deliver stable electrical power adapted to the needs of the electrical loads and ensures the operational balance of the electrical distribution system. In summary, the invention thus makes it possible to switch from a parallel, low-voltage distribution architecture to a series, medium-voltage distribution architecture.The invention is particularly advantageous when implemented in an electrical distribution system that is a data processing center in which the electrical loads are arranged in racks.

[0011] Advantageously, for each conversion module, maintaining the apparent power of the conversion module equal to a target value is achieved by increasing the reactive power of the conversion module when the active power value of The operating power imposed by the associated electrical load decreases, and the reactive power of the conversion module decreases as the active operating power value imposed by the associated electrical load increases.

[0012] Advantageously, for each conversion module, the amplitude of the alternating voltage at the input terminals of the conversion module is regulated to be maintained between a lower voltage limit and an upper voltage limit.

[0013] The invention also relates to an electrical distribution system, in particular a data processing center, comprising: - a power supply device, configured to deliver a first current, which is a single-phase alternating current, associated with a first voltage, which is a single-phase alternating voltage between 10 kV and 35 kV, - a plurality of electrical loads, which are for example data servers arranged in racks, - a plurality of conversion modules, the conversion modules being respectively associated with the electrical loads, • each conversion module comprising input terminals and output terminals, • the input terminals of all the conversion modules being connected in series with each other and with the power supply device, the first current thus flowing between the input terminals of all the conversion modules, the first voltage thus being applied to all the conversion modules, • the output terminals of each conversion module being connected to the electrical load associated with the conversion module

[0014] Each conversion module of this data processing center comprises: - a group of transistors, connected between the input terminals of the conversion module, - at least one capacitive element, connected to the transistor group, - a converter, connected to the transistor group and the output terminals of the conversion module, and - an electronic control unit, configured to control each transistor in the transistor group.

[0015] Furthermore, the transistor group of each conversion module is configured to deliver a DC voltage and a DC current to the converter of the conversion module, from the AC voltage at the input terminals of the conversion module and the AC current flowing between the input terminals of the conversion module and the converter of each conversion module is configured to deliver to the associated electrical load a constant DC voltage between 48 V and 400 V and a direct current, from the direct voltage and direct current delivered by the transistor group of the conversion module.

[0016] In addition, the electronic control unit of each conversion module is configured to regulate the amplitude of the alternating voltage at the input terminals of the conversion module and the phase shift between the alternating voltage at the input terminals of the conversion module and the alternating current flowing between the input terminals of the conversion module, by controlling the transistor group of the conversion module and by means of at least one capacitive element of the conversion module.

[0017] According to other advantageous aspects of the invention, the electrical distribution system comprises one or more of the following features, taken individually or in all technically possible combinations:

[0018] - The electrical distribution system is configured to be controlled by the control method as described above. For each conversion module, the electronic control unit is configured to implement regulation of the DC voltage delivered by the conversion module to the associated electrical load and to maintain the apparent power of the conversion module equal to the target value.

[0019] - The transistor group of each conversion module comprises transistors insulated grid bipolar devices.

[0020] - The plurality of conversion modules comprises at least ten modules of conversion.

[0021] - Each conversion module further includes a protection circuit configured to circulate the single-phase alternating current delivered by the power supply device between the input terminals of the conversion module by short-circuiting the transistor group in case of failure of the conversion module and / or the associated electrical load.

[0022] - The power supply device is configured to deliver alternating current three-phase and an alternating voltage between 10 kV and 35 kV per phase, the first current corresponding to the first phase of the three-phase alternating current and the first voltage corresponding to the first phase of the three-phase alternating voltage, and the plurality of conversion modules form a first group of conversion modules. Furthermore, the electrical distribution system includes, in addition, a second group of conversion modules and a third group of conversion modules, the conversion modules of the second and third groups being identical to the conversion modules of the first group, and each being respectively associated with an electrical load. In addition: • The conversion modules of the first group of conversion modules are connected in series to the power supply device so that the first current flows between the input terminals of all the conversion modules of the first group and so that the first voltage is applied to all the conversion modules of the first group, • The conversion modules of the second group of conversion modules are connected in series to the power supply device so that a second single-phase alternating current, corresponding to a second phase of the three-phase alternating current, flows between the input terminals of all the conversion modules of the second group, and so that a second single-phase alternating voltage, corresponding to a second phase of the three-phase alternating voltage, is applied to all the conversion modules of the second group, and • The conversion modules of the third group of conversion modules are connected in series to the power supply device so that a third single-phase alternating current, corresponding to a third phase of the three-phase alternating current, flows between the input terminals of all the conversion modules of the third group and so that a third single-phase alternating voltage, corresponding to a third phase of the three-phase alternating voltage, is applied to all the conversion modules of the third group.

[0023] - The electrical distribution system is a data processing center comprising a plurality of bays, each electrical load and each conversion module being associated with a bay, each electrical load being disposed in the associated bay, each conversion module being fixed to the associated bay or integrated into the associated bay.

[0024] The invention will become clearer upon reading the following description, given solely by way of non-limiting example, and made with reference to the drawings in which:

[0025] [Fig-1] Fig. 1 is a schematic representation of a distribution system electrical according to the invention, comprising several conversion modules.

[0026] [Fig.2] The [Fig.2] is a schematic representation of one of the conversion modules of the electrical distribution system of the [Fig.1].

[0027] [Fig.3] The [Fig.3] includes two diagrams illustrating an adjustment of the apparent power of the conversion modules of the electrical distribution system of the [Fig.1].

[0028] [Fig.4] Fig.4 is a diagram illustrating the impact of the phase shift between the voltage and current of a conversion module on the active power and on the power reactive of the conversion module, the conversion module belonging to the electrical distribution system of the [Fig.l].

[0029] [Fig. 5] Fig. 5 is a schematic representation of part of the system of electrical distribution of the [Fig.l].

[0030] An electrical distribution system 10 according to the invention is schematically represented in [Fig.1].

[0031] In the example, the electrical distribution system 10 is a data processing center.

[0032] The following description relates to the implementation of the invention in a data center, but is applicable to other types of electrical distribution systems. For example, the electrical distribution system could be a power supply system for machine tools, for instance in the semiconductor industry, a power supply system for control devices, or even a building's electrical distribution system. In practice, the invention is usable in any industrial or commercial field involving homogeneous and distributed groups of electrical loads operating at low voltage and medium power, i.e., consuming power from tens to hundreds of kW, and being relatively stable over time.

[0033] The data processing center 10 includes a power supply device 12, which is connected to an external power supply network and configured to deliver a three-phase current system, i.e., three-phase alternating current and an alternating voltage between 10 kV and 35 kV per phase. This range of 10 kV to 35 kV is more generally referred to as medium voltage. The power supply device 12 thus delivers three phases, represented respectively by the letters U, V, and W in [Fig. 1].

[0034] In the following description, the first current and voltage are designated as the alternating current and voltage corresponding to a first phase of the three-phase alternating current and voltage delivered by the power supply device 12; the second current and voltage are designated as the alternating current and voltage corresponding to a second phase of the three-phase alternating current and voltage delivered by the power supply device 12; and the third current and voltage are designated as the alternating current and voltage corresponding to a third phase of the three-phase alternating current and voltage delivered by the power supply device 12.

[0035] The power supply device 12 also includes a neutral, represented by the letter N on the [Fig.1].

[0036] The operation of the power supply device 12, known in itself, is not detailed.

[0037] The data processing center 10 comprises a plurality of bays 14. Each rack contains at least one electrical load. Each electrical load in a rack corresponds to a piece of equipment belonging to an information system, such as mainframe computers, servers, data storage devices, network equipment, and / or telecommunications equipment. Preferably, the electrical loads in a rack are data servers.

[0038] Only two electric charges 16 are shown in [Fig. 1] for clarity of the figure. In practice, it is understood that each of the bays 14 includes at least one electric charge 16.

[0039] Preferably, the bays 14 of the data processing center 10 are standard-sized cabinets, in a manner known per se. Thus, the design of the bays 14, known per se, is not detailed.

[0040] In practice, the electrical loads 16 must be supplied with a constant direct current voltage between 48 V and 400 V, for example equal to 48 V. This range of 48 V to 400 V is more generally referred to as low voltage.

[0041] The electrical loads 16 of a bay 14 consume electrical power, called active power or real power, which depends on the nature of the electrical load and its operating state, in particular whether it is switched on or off and its percentage of utilization. In practice, the active power consumed by the electrical loads 16 of a bay 14 can reach up to 100 kW, or even more. In other words, a bay 14 operates at medium power, that is, between 10 kW and 100 kW.

[0042] To enable the power supply of the bays 14 from the power supply device 12, the data processing center 10 includes as many conversion modules as there are bays 14. Thus, each conversion module is respectively associated with a bay 14. In other words, the data processing center 10 includes as many bays as there are conversion modules.

[0043] Advantageously, each conversion module is fixed to the associated bay 14 or is integrated into the associated bay, preferably being arranged in a case or drawer of standardized dimensions.

[0044] In practice, the conversion modules are divided into three groups: a first group of 20U conversion modules is connected to the first phase U of the power supply device 12, a second group of 20V conversion modules is connected to the second phase V of the power supply device and a third group of 20W conversion modules is connected to the third phase W of the power supply device.

[0045] Advantageously, the conversion modules of the three groups of conversion modules are all identical.

[0046] Preferably, each group of conversion modules comprises a minimum number of 20U, 20V, or 20W conversion modules sufficient to meet the requirements of a medium-voltage network as defined in IEC 62271-1, which entered into force on April 10, 2021, and more specifically as defined in section 5.3 of that standard (Rated insulation level (Ud, Up, U)). This standard, for medium-voltage switchgear, defines in particular the maximum acceptable continuous voltage, the maximum acceptable transient overvoltage for a duration of one minute, and the lightning surge voltage that must be withstood. Thus, each group of conversion modules preferably comprises at least 10 conversion modules, and preferably between 10 and 20 conversion modules, for example, 16 conversion modules. Preferably, all groups of conversion modules comprise the same number of conversion modules.

[0047] The data processing center also includes a filter 17, which is a medium-voltage filter, that filters the first, second, and third voltages U, V, and W upstream of the conversion modules 20U, 20V, and 20W. The filter 17 includes, for example, three inductive elements, such as coils. The filter 17 also attenuates transient voltage variations in the first, second, and third phases, which could damage or disrupt the conversion modules 20U, 20V, and 20W.

[0048] In the following description, only the 20U conversion modules of the first group of conversion modules are described. The design and operation of the 20V and 20W conversion modules of the second and third groups of conversion modules are identical to those of the 20U conversion modules of the first group of conversion modules. By analogy, everything described concerning the 20U conversion modules and the first phase U of the power supply device 12 is also applicable to the 20V conversion modules and the second phase V, as well as to the 20W conversion modules and the third phase W.

[0049] Each 20U conversion module includes input terminals 22 and output terminals 24.

[0050] The input terminals 22 of all the 20U conversion modules are connected in series with each other and to phase U of the power supply 12. Thus, the first current delivered by the power supply 12 flows between the input terminals 22 of all the 20U conversion modules, and the first voltage is applied to all the 20U conversion modules. In other words, the 20U conversion modules are all connected in series to phase U so that the first current flows between the input terminals 22 of each of the 20U conversion modules, and the first voltage is applied to the terminals of the first group of 20U conversion modules. that is to say that the first voltage is applied to all 20U conversion modules.

[0051] The 20U conversion modules are also connected in series to the neutral N. Thus, the first voltage corresponds to the voltage measured between the phase U at the level of the power supply device 12 and the neutral N.

[0052] Since the same applies to the 20V and 20W conversion modules, the data processing center 10, which comprises three groups of conversion modules each connected to one phase of the power supply device 10 and supplied with medium voltage, is thus equivalent to a three-phase medium voltage load in star connection.

[0053] The output terminals 24 of a 20U conversion module are connected to the bay 14 associated with this 20U conversion module.

[0054] Furthermore, each 20U conversion module includes a converter, which is connected to the output terminals 24 of the conversion module and is configured to deliver to the bay 14 associated with this 20U conversion module a constant DC voltage between 48 V and 400 V, i.e., a low voltage, and a DC current, from the AC voltage at the input terminals 22 of the 20U conversion module and from the AC current flowing between the input terminals 22 of the conversion module, i.e., from the first current. The converter of each 20U conversion module thus makes it possible to deliver active power to the bay 14 associated with the conversion module, so as to electrically supply at least one electrical load 16 of the bay.

[0055] Thus, each 20U conversion module delivers the active power required for the operation of the electrical loads 16 of the bay 14 associated with the conversion module from the first voltage and the first current thanks to its converter.

[0056] The data processing center 10 also includes three data buses, designated 18U, 18V and 18W respectively.

[0057] The 18U data bus connects all the 20U conversion modules of the first group and allows data exchange between the 20U conversion modules. Preferably, the 18U data bus is a CAN data bus, from the English acronym Controller Area Network, defined by the ISO 11898 standard.

[0058] Similarly, the 18V data bus links together all the 20V conversion modules of the second group and the 18W data bus links together all the 20W conversion modules of the third group.

[0059] An example of a 20U conversion module belonging to the data processing center 10 is now described with reference to [Fig.2].

[0060] Advantageously, the 20U conversion module includes a protection circuit 26 which is connected between the input terminals 22 of the conversion module and which is configured to circulate the first current delivered by the power supply device 12 between the input terminals 22 of the 20U conversion module by short-circuiting the transistor group 30 in the event of failure of the conversion module and / or of at least one electrical load 16 of the bay 14 associated with the conversion module.

[0061] When a 20U conversion module is short-circuited by its protection circuit 26, it is said to be inactive and cannot deliver power to the associated bay. Otherwise, it is said to be active and is able to supply power to the associated bay.

[0062] In the example, the protection circuit 26 is a switch, referred to as a bypass switch, or bridging switch. The switch 26 is normally open. When commanded to be closed, the switch 26 allows the 20U conversion module to be short-circuited by directly connecting the input terminals 22 together, thus allowing a 20U conversion module and its associated bay 14 to be disconnected without interrupting the series connection of the other 20U conversion modules in the first group of conversion modules.

[0063] The 20U conversion module includes an electronic control unit 28.

[0064] The 20U conversion module comprises a group of 30 transistors, connected between the input terminals 22 of the 20U conversion module. In other words, the first current generated by the power supply device 12 flows between the input terminals 22 of the 20U conversion module in the first group of transistors 30.

[0065] The electronic control unit 28 is configured to control each transistor in the transistor group 30.

[0066] In practice, the transistors in the transistor group 30 are controlled by the electronic control unit 28 so that the transistor group 30 acts as a rectifier, that is, as an AC-DC converter. Thus, the transistor group 30 is supplied via the input terminals 22 by the first current and voltage delivered by the power supply device 12 and delivers an intermediate voltage, which is preferably a DC voltage between 600 V and 1000 V. In other words, the transistor group 30 is controlled to convert the first AC voltage, between 10 kV and 35 kV, into an intermediate DC voltage between 600 V and 1000 V.

[0067] The operation of the transistor group 30 as a rectifier, known per se, is not described in further detail.

[0068] Preferably, the transistors in the transistor group 30 are metal-oxide gate field-effect transistors, more commonly known as MOSFETs, the English acronym for metal-oxide-semiconductor field-effect transistor. Even more preferably, the transistors are of the silicon carbide MOSFET type, known by the acronym " SIC MOSFET. The use of such transistors allows the transistor group to operate reliably while maximizing its efficiency. Furthermore, these transistors also allow for higher operating frequencies, thus contributing to the optimization of the data processing center 10.

[0069] Alternatively, the transistors in the transistor group 30 are insulated-gate bipolar transistors, more commonly known as IGBTs, an acronym for Insulated-gate bipolar transistor.

[0070] As described above, the 20U conversion module includes a converter, denoted 32, connected on one side to the transistor group 30 and on the other side to the output terminals 24 of the conversion module. The converter 32 converts the intermediate DC voltage supplied by the transistor group 30 into the low voltage supplied to the bay 14 associated with the conversion module.

[0071] The converter 32 comprises a first group of transistors 34, an intermediate frequency transformer 36, and a second group of transistors 36, which together form a first DC-DC conversion stage that converts the intermediate voltage into a lower voltage DC voltage, in this example 400 V. The value of this voltage may differ from 400 V but is preferably between 200 V and 600 V. This voltage range corresponds to voltages that can be directly used in standard racks equipped with power supply units (PSUs) capable of transforming this voltage to 48 V and / or 12 V.

[0072] The medium frequency transformer 36 ensures isolation between the medium voltage and the low voltage according to the constraints defined in the standards IEC 60076-3 in force in 2013 and IEC 62271-1 in force on April 10, 2021.

[0073] The operation of the first DC-DC conversion stage, formed by the first group of transistors 34, the medium-frequency transformer 36, and the second group of transistors 38, which is known per se, is not detailed. By way of example, the first conversion stage may be formed by an LLC converter or by a DAB converter, an acronym for dual active bridge.

[0074] Preferably, the entire first DC-DC conversion stage forms an SST transformer, an acronym for the English solid-state transformer.

[0075] In the example, the converter 32 also includes a second DC-DC conversion stage, formed by a third group of transistors 40, which is connected to the second group of transistors 38 and which converts the 400 V DC voltage obtained from the first DC-DC conversion stage into a lower voltage DC voltage, in the example 48 V. The value of this voltage may be different from 48 V but is preferably between 48 V and 54 V.

[0076] The operation of the second DC-DC conversion stage formed by the third group of transistors 40, known per se, is not detailed. By way of example, the second conversion stage may be formed by a Buck converter, also known as a series chopper.

[0077] The second DC-DC conversion stage of the converter 32 is connected to the output terminals 24 of the conversion module 20U, so that the DC voltage of 48 V is delivered to the output terminals 24 and thus to the bay 14 associated with the conversion module.

[0078] The second DC-DC conversion stage of converter 32 is optional: when it is not present, the first DC-DC conversion stage of converter 32 is connected to the output terminals 24 of the 20U conversion module, so that the 400 V DC voltage is directly delivered to the output terminals 24 and thus to the bay 14 associated with the conversion module. In practice, the decision to integrate a second DC-DC conversion stage into converter 32 of the 20U conversion module depends on the operating voltage of the electrical loads 16 in the associated bay 14.

[0079] Thanks to the medium frequency transformer 36, the 20U conversion module benefits from galvanic isolation between its input terminals 22 and its output terminals 24, with an isolation level between 20kV and 50kV between its input terminals 22 and its output terminals 24, which provides protection to the electrical loads 16 of the associated bay 14.

[0080] Thanks to the group of transistors 30 operating as a rectifier and thanks to the two conversion stages of the conversion module 20U, the electrical loads 16 of the associated bay 14 benefit from effective protection by avoiding the transmission of faults present in the power supply delivered by the power supply device, such as voltage peaks and troughs.

[0081] The 20U conversion module includes at least one capacitive element 42, connected to the transistor group 30 and, in the example, also connected to the second transistor group 34 of the converter 32. In the example, the at least one capacitive element 42 is formed by two capacitors 42. In a non-shown variant of the invention, the at least one capacitive element 42 comprises a different number of capacitors and / or one or more other capacitive electronic components.

[0082] A method for controlling the data processing center 10 is now described, the control method being in accordance with the invention.

[0083] The control method is described with reference to the first group of 20U conversion modules, i.e. with reference to the first phase U delivered by the power supply device 12. This control method applies in the same way to the second and third groups of 20V, 20W conversion modules.

[0084] In the following description, when reference is made to a voltage, this voltage is considered to be at the fundamental frequency of the network, i.e. at the fundamental frequency delivered by the power supply device 12, for example equal to 50 Hz. Thus, harmonic phenomena are not described.

[0085] For the first group of 20U conversion modules in the data processing center 10, the following parameters are imposed: - The active power consumed by each bay 14 is imposed by at least one electrical load 16 of the bay and thus corresponds to the active operating power of at least one electrical load of the bay. - The first voltage, that is to say the voltage measured between phase U at the level of the power supply device 12 and neutral N and applying to all the conversion modules 20U, is imposed by the power supply device 12 and is constant. - The first current, that is to say the current delivered by the power supply device 12 and circulating in all the conversion modules 20U, is imposed by the electrical loads 16 of the bays 14 and results from the sum of the currents absorbed by the electrical loads 16, neglecting line losses. The apparent power delivered by the power supply 12 is determined by the first voltage and the first current, as it is proportional to the product of the first voltage and the first current.

[0086] Furthermore, the architecture of the data processing center 10, with the 20U conversion modules connected in series to the first phase of the power supply 12, implies that the sum of the voltage across the input terminals 22 of each 20U conversion module depends on the first voltage delivered by the power supply 12 and the power regulation implemented by the control method. In practice, the first voltage delivered by the power supply 12 is equal to the sum of the voltage across the input terminals 22 of each 20U conversion module and the voltage across the filter 17, for the first phase.

[0087] In addition, for each 20U conversion module, the voltage between the input terminals of the conversion module must be controlled by being maintained between a predefined lower limit and a predefined upper limit, in particular to ensure the proper functioning of the transistor group 30.

[0088] Since the first voltage is constant, this data center architecture 10 requires continuous balancing of the voltage across the input terminals of each 20U conversion module, so that the sum of the voltages across each of the 20U conversion modules remains balanced and so that the voltage between the input terminals of each conversion module is maintained within the lower limit predefined and predefined upper limit. The control method of the invention therefore aims to balance the voltages between all the 20U conversion modules.

[0089] Furthermore, since the first current is common to all 20U conversion modules, balancing the voltages of the 20U conversion modules is equivalent to balancing the apparent power of the conversion modules. Indeed, the apparent power of a 20U conversion module is proportional to the product of the first current flowing between its input terminals 22 and the voltage between its input terminals, the first current being imposed.

[0090] The problem is that variations in active power consumed by a bay 14 can lead to an imbalance in the apparent power of the associated 20U conversion module: the control method of the invention aims to prevent this imbalance.

[0091] Thus, to maintain the operating balance of the first group of 20U conversion modules, the objective of the control method of the invention is to distribute the apparent power delivered by the power supply 12 among all the 20U conversion modules, so that the apparent powers of all the conversion modules are equal. Furthermore, since the sum of the apparent powers of the conversion modules is equal to the apparent power delivered by the power supply 12, the apparent powers of all the conversion modules are also constant when the apparent power delivered by the power supply 12 is constant.

[0092] The control method of the invention is particularly relevant in applications where the first current is relatively stable, that is to say in applications where the electrical power consumed by all the electrical loads 16 is relatively homogeneous, in other words in applications where the active power consumed by the bays 14 varies little over time.

[0093] Thus, as a first approximation, it is possible to consider that the sum of the active powers consumed by all the bays 14 remains homogeneous and uniformly distributed over time, so that the apparent power delivered by the power supply device 12 also remains constant over time, and therefore that the apparent power of each conversion module 20U also remains constant over time.

[0094] The target value at which we seek to maintain the apparent power of a 20U conversion module equal is therefore equal to the value of the apparent power delivered by the power supply device 12 divided by the number of 20U conversion modules connected in series to the power supply device 12, counting only the active 20U conversion modules, i.e. not counting any possible 20U conversion modules short-circuited by their protection circuit 26.

[0095] To achieve this objective of equal apparent power for a 20U conversion module across all conversion modules, despite the variability of the active power consumed by the electrical loads 16 in the bay 14 associated with the conversion module, the control method of the invention aims to vary the reactive power of the conversion module. In other words, for each 20U conversion module, the variations in active power consumed by the associated bay 14 are compensated by a variation in the reactive power of the conversion module.

[0096] Thus, each 20U conversion module is ordered to: - regulate the DC voltage delivered by the 20U conversion module to the associated bay 14, based on the value of the active operating power imposed by at least one electrical load 16 of the bay, so that the active power delivered by the 20U conversion module is equal to this active operating power, and - maintain the apparent power of the 20U conversion module equal to the target value, so that the apparent powers of all the conversion modules (20U) are equal to each other, by regulating the amplitude of the alternating voltage at the input terminals 22 of the conversion module and a phase shift between the alternating voltage at the input terminals of the conversion module and the alternating current flowing between the input terminals of the conversion module, based on: • of the active power delivered by the 20U conversion module to the associated bay 14, imposed by at least one electrical load 16 of the bay, • of the first voltage and current delivered by the power supply device 12 to the plurality of conversion modules 20U, and • the number of active 20U conversion modules.

[0097] In practice, the regulation of the DC voltage delivered by the 20U conversion module to the associated bay 14 consists of maintaining constant the low voltage delivered to the bay 14, despite variations in active operating power of the electrical load 16 of the bay, because these variations in active operating power would cause variations in the voltage delivered by the conversion module to the bay in the absence of regulation.

[0098] Advantageously, each 20U conversion module knows the measurements of the first voltage and the first current as well as the number of active 20U conversion modules thanks to the 18U data bus, which allows the exchange of this information between all the 20U conversion modules.

[0099] In other words, each 20U conversion module will act on the phase shift between the voltage between its input terminals 22 and the first current flowing between its input terminals, as well as on the amplitude of the voltage between its input terminals, to increase or decrease its reactive power according to the decreases or increases of the active power delivered to the associated bay, so as to maintain a constant apparent power.

[0100] Thus, maintaining the apparent power of a 20U conversion module equal to the target value is achieved by increasing the reactive power of the conversion module when the active operating power value imposed by at least one electrical load of the associated bay decreases and by decreasing the reactive power of the conversion module when the active operating power value imposed by at least one electrical load of the associated bay increases.

[0101] In addition, the regulation of the amplitude of the alternating voltage at the input terminals 22 of the 20U conversion module aims to maintain this voltage between the predefined lower limit and the predefined upper limit.

[0102] In practice, the adjustment of the amplitude of the alternating voltage at the input terminals 22 of the conversion module 20U and the adjustment of the phase shift between the alternating voltage at the input terminals of the conversion module and the alternating current flowing between the input terminals of the conversion module, i.e. the regulation of the apparent power at the input of a conversion module 20U, are carried out by the electronic control unit 28 of the conversion module, by controlling the group of transistors 30 and by means of at least one capacitive element 42, which then forms a DC voltage source for the group of transistors 30.

[0103] The group of transistors 30 of a 20U conversion module thus has two functions: on the one hand, to rectify the alternating voltage between the input terminals 22 of the conversion module to deliver the intermediate direct voltage to the converter 32 and then to the associated bay 14, and on the other hand to regulate the reactive power of the conversion module.

[0104] Thus, the variations in amplitude and phase of the voltage between the input terminals 22 of a 20U conversion module allow the distribution of the apparent power of this conversion module between active power and reactive power.

[0105] In practice, when the data processing center 10 is in steady state, i.e. when the intensity of the first current is substantially constant, then the amplitude of the voltage between the input terminals 22 of a 20U conversion module remains constant and only the phase shift between the alternating voltage at the input terminals of the conversion module and the alternating current flowing between the input terminals of the conversion module varies when the active power delivered to the associated bay varies to maintain a constant apparent power.

[0106] Two diagrams illustrating this reactive power adjustment of each 20U conversion module to maintain a constant apparent power are shown in [Fig. 3]. In this figure, two simplified diagrams are represented, each corresponding to a hypothetical case where the first group of 20U conversion modules comprises three 20U conversion modules. The apparent powers of these three modules are represented respectively as S1, S2, and S3, and each is decomposed into the sum of an active power P1, P2, P3 and a reactive power Q1, Q2, and Q3.

[0107] Diagram A), shows nominal operation, in which the active powers PI, P2, P3 delivered by each of the three 20U conversion modules to their respective bays 14 are close.

[0108] Diagram B illustrates an unbalanced operation, not representative of the normal operation of the data processing center 10, in which the second 20U conversion module delivers to its respective bay 14 a significantly lower active power P2 than the active powers PI, P3 delivered by the first and third conversion modules to their respective bays. It is clear that such an unbalanced operation leads to the appearance of significant reactive power in the first group of 20U conversion modules, which reduces the efficiency of the data processing center and, in particular, its throughput.

[0109] These graphical representations illustrate the distribution of active and reactive power between the three 20U conversion modules, applying Boucherot's method, also known as Boucherot's theorem. It can be seen that the total apparent power S delivered by the power supply device 12 is equal to the sum of the apparent powers S1, S2, and S3, and that, in order to maintain equal apparent power between all the 20U conversion modules, each conversion module acts as a variable impedance; that is, each conversion module varies its power factor, corresponding to the ratio of its active power to its apparent power, by modifying its reactive power according to its active power.

[0110] This concept is illustrated in the diagram in [Fig.4], on which are represented the first current flowing between the input terminals 22 of a 20U conversion module, denoted "I", as well as two distinct theoretical voltages between the input terminals of the conversion module: - a first voltage VI, corresponding to a phase shift 01 between the first current and the voltage, and - a second voltage V2, corresponding to a phase shift 02 between the first current and the voltage, the phase shift 02 being smaller than the phase shift 01.

[0111] On this graph, the abscissa represents the active power P of the 20U conversion module and the ordinate represents the reactive power Q of the module conversion. We then understand that the greater the phase shift between voltage and current, the more the active power P decreases and the reactive power Q increases.

[0112] To implement the reactive power regulation of a 20U conversion module, i.e. the amplitude of the voltage between its input terminals 22 and the phase shift between this voltage and the first current, the electronic control unit 28 of each 20U conversion module first obtains the following data: - the number of 20U conversion modules, obtained via the 18U data bus; - the value of the first voltage delivered by the power supply device 12, obtained via the data bus 18U; - the value of the first current delivered by the power supply device 12, measured at the input terminals 22 of the conversion module 20U or, alternatively, obtained via the data bus 18U; - the voltage value between input terminals 22 of the 20U conversion module, as measured by the conversion module; and - the value of the active power delivered by the converter 32 of the 20U conversion module to the associated bay 14.

[0113] From these data, the electronic control unit 28 calculates the phase shift between the voltage between the input terminals 22 of the conversion module 20U and the first current flowing between the input terminals of the conversion module, and calculates the target value of apparent power of the conversion module 20U, that is to say the apparent power that the conversion module must take to balance the operation of the modules in series on the first phase U delivered by the power supply device 12 of the data processing center 10.

[0114] Next, the electronic control unit 28 regulates the following parameters of the conversion module 20U: - the voltage between the input terminals 22 of the 20U conversion module and the phase shift between the voltage between the input terminals 22 of the 20U conversion module and the first current flowing between the input terminals of the conversion module, by driving the transistors of the first group of transistors 30 and by means of at least one capacitive element 42, to achieve the target apparent power value; and - the active power delivered by the converter 32 to the associated bay 14, by controlling the transistors of the first, second and, where applicable, third groups of transistors 34, 38, 40 of the converter 32.

[0115] This operation of the electronic control unit 28 of a 20U conversion module is schematically illustrated in [Fig. 5], in which the data processing center 10 and said 20U conversion module are shown. In a simplified manner. In particular, the other 20U conversion modules and the 12 power supply are shown with a single box. It is understood that said 20U conversion module is connected in series with the other conversion modules and the 12 power supply as shown in [Fig. 1].

[0116] In [Fig.5], the measurements taken by the electronic control unit 28 are represented by arrows pointing towards the electronic control unit and the commands issued by the electronic control unit 28 are represented by arrows coming out of the electronic control unit.

[0117] Each electronic control unit 28 performs these actions in real time, that is to say, in practice, at the fundamental frequency of the network supplying the power supply device 12 with electrical energy, for example 50 Hz.

[0118] Advantageously, the failure of a 20U conversion module results in the disconnection of the associated bay 14, but does not disrupt the operation of the other conversion modules. Indeed, when a conversion module fails and becomes inactive, the electronic control units 28 of the other conversion modules are informed, since the data bus 18U informs all conversion modules of the number of active conversion modules. In such a situation, the voltage between the input terminals of the active conversion modules will increase to compensate for the loss of the failed conversion module.

[0119] The control method according to the invention therefore makes it possible to ensure permanent balancing of the voltages at the input terminals 22 of the 20U conversion modules and has the advantage of operating without centralized control, i.e. centralized control of the 20U conversion modules is not necessary, each conversion module operating autonomously thanks to its electronic control unit 28. This decentralized control is particularly advantageous for simplifying the management of the data processing center 10.

[0120] Advantageously, the data processing center is designed so that, in steady state, the intensities of the first, second, and third currents are substantially equal to each other; that is, all the bays 14 associated respectively with the 20U conversion modules, the 20V conversion modules, and the 20W conversion modules consume substantially equal electrical power. Thus, the first, second, and third phases U, V, and W are balanced.

[0121] Thanks to the control method of the invention, it is possible to connect all the bays 14 in series to a medium-voltage source and thus obtain the data center architecture 10 of the invention. In such an architecture, power transmission from the power supply 12 to the bays 14 is carried out at medium voltage, whereas in data center architectures, this transmission is carried out at low voltage. The fact that this Power transmission at medium voltage rather than low voltage allows the associated current intensity to decrease, at equal power, which allows a reduction in the cross-section of the electrical conductors through which this power is transmitted.

[0122] Thus, compared to a known architecture in which all the bays are connected in parallel to a power supply delivering a low voltage, the installation cost of the data center 10 according to the invention is reduced by at least 15%, notably due to the decrease in the amount of copper required for the electrical connections, since their cross-section is reduced. Furthermore, the footprint of the data center 10 is reduced by at least 20%, since the 20U conversion modules can be integrated into the bays 14 or attached to the bays, and since it is no longer necessary to use medium-voltage to low-voltage converters supplying the bays 14 in parallel.

[0123] In addition, compared to a traditional installation, the installation cost, i.e. deployment cost, of the data processing center 10 according to the invention is reduced, since the deployment of the 20U, 20V, 20W conversion modules in series offers more flexibility and modularity and since the installation of medium voltage - low voltage transformers is no longer necessary.

[0124] Finally, compared to a traditional installation, the data processing center 10 according to the invention is more easily modifiable during its use, because it is easier to add new bays 14 to an existing installation with a serial architecture, and its maintenance cost is reduced, because replacing a faulty 20U, 20V, 20W conversion module is easy.

[0125] The data processing center 10 of the invention is particularly suitable for data centers, because in this type of application, the electrical loads 16 are relatively stable and relatively uniformly distributed between the bays 14. Indeed, in a system with too great a disparity between the electrical loads, a significant amount of reactive power may be generated by certain conversion modules to compensate for the low power consumed by their load, which reduces the efficiency of the data processing center.

[0126] In a non-shown variant of the invention, the power supply device 12 delivers a single-phase voltage, instead of a three-phase voltage. In such a variant, the operation of the first group of conversion modules 20U remains unchanged and the data processing center 10 comprises only this first group of conversion modules.

[0127] In a non-shown variant of the invention, the 20U, 20V and 20W conversion modules are not controlled by their electronic control unit 28, but by a centralized electronic control unit of the data processing center 10. Such a variant has the advantage of allowing better monitoring of the occurrence of faults within the conversion modules and simpler management of reconfigurations of the conversion modules in the event of failure and / or replacement of one of them, but increases the complexity of the implementation of the control method of the invention and entails a risk of disruption of this method, in the event of a fault during the exchange of data and commands between the centralized electronic control unit and the conversion modules and / or because of the distance that may separate the centralized electronic control unit from the conversion modules.

[0128] The invention has been described in an example where the power distribution system is a data center, each conversion module being associated with a bay 14 comprising one or more electrical loads 16. Alternatively, a more general way of describing the invention, also applicable where the power distribution system is not a data center, is to consider that each conversion module is associated with an electrical load 16, whether this electrical load 16 is a bay 14, an electric motor, a control device, or any other power-consuming device. Thus, in such a description, a bay 14 and the electrical loads 16 associated with it are functionally identical to an electrical load 16.

[0129] Any feature described for a variant in the foregoing may be implemented for the other variants described above, provided that it is technically feasible.

Claims

1. Demands Method for controlling an electrical distribution system (10), the electrical distribution system (10) comprising: - a power supply device (12), configured to deliver a first current, which is a single-phase alternating current, associated with a first voltage, which is a single-phase alternating voltage between 10 kV and 35 kV, - a plurality of electrical loads (16), - a plurality of conversion modules (20U), the conversion modules being respectively associated with the electrical loads (16), • each conversion module (20U) comprising input terminals (22) and output terminals (24), • the input terminals (22) of all the conversion modules (20U) being connected in series with each other and with the power supply device (12), the first current thus flowing between the input terminals (22) of all the conversion modules, the first voltage thus being applied to all the conversion modules, • the output terminals (24) of each conversion module (20U) being connected to the electrical load (16) associated with the conversion module, • each conversion module (20U) comprising a converter (32), connected to the output terminals (24) of the conversion module and configured to deliver to the associated electrical load (16) a DC voltage between 48 V and 400 V and a DC current, from the AC voltage at the input terminals (22) of the conversion module (20U) and the AC current flowing between the input terminals of the conversion module, thus delivering active power supplying the associated electrical load (16), The control method comprises, for each conversion module (20U): - regulating the DC voltage delivered by the conversion module (20U) to the associated electrical load (16), to maintain it at a constant value, based on an active operating power value imposed by the electrical load, and - maintaining an apparent power of the conversion module (20U) equal to a target value, so that the apparent powers of all the conversion modules (20U) are equal to each other, by regulating an amplitude of the AC voltage at the input terminals (22) of the conversion module and a phase shift between the AC voltage at the input terminals of the conversion module and the AC current flowing between the input terminals of the conversion module, based on: • the active power delivered by the conversion module (20U) to the associated electrical load (16),• the alternating voltage and alternating current delivered by the power supply device (12) to the plurality of conversion modules (20U), and • the number of conversion modules (20U).

2. A control method according to claim 1, wherein, for each conversion module (20U), maintaining the apparent power of the conversion module equal to a target value is achieved by increasing the reactive power of the conversion module when the active operating power value imposed by the associated electrical load (16) decreases and by decreasing the reactive power of the conversion module when the active operating power value imposed by the associated electrical load increases.

3. A control method according to any one of claims 1 and 2, wherein, for each conversion module (20U), the amplitude of the alternating voltage at the input terminals (22) of the conversion module is regulated to be maintained between a lower voltage limit and an upper voltage limit.

4. Electrical distribution system (10), comprising: a power supply device (12), configured to deliver a first current, which is a single-phase alternating current, associated with a first voltage, which is a single-phase alternating voltage between 10 kV and 35 kV, a plurality of electrical loads (16), a plurality of conversion modules (20U), the conversion modules being respectively associated with the electrical loads (16), each conversion module (20U) comprising input terminals (22) and output terminals (24), the input terminals (22) of all the conversion modules (20U) being connected in series with each other and with the power supply device (12), the first current thus flowing between the input terminals of all the conversion modules, the first voltage thus being applied to all the conversion modules, the output terminals (24) of each conversion module (20U) being connected to the electrical load (16) associated with the conversion module, in which each conversion module (20U) comprises: a group of transistors (30), connected between the input terminals (22) of the conversion module (20U), at least one capacitive element (42), connected to the group of transistors (30), a converter (32), connected to the transistor group (30) and to the output terminals (24) of the conversion module (20U), and an electronic control unit (28), configured to control each transistor in the transistor group (30), in which the transistor group (30) of each conversion module (20U) is configured to deliver to the converter (32) of the conversion module a DC voltage and a DC current, from the AC voltage at the input terminals (22) of the module conversion (20U) and alternating current flowing between the input terminals of the conversion module, wherein the converter (32) of each conversion module (20U) is configured to deliver to the associated electrical load (16) a constant DC voltage between 48 V and 400 V and a DC current, from the DC voltage and DC current delivered by the transistor group (30) of the conversion module, and wherein the electronic control unit (28) of each conversion module (20U) is configured to regulate the amplitude of the AC voltage at the input terminals (22) of the conversion module and the phase shift between the AC voltage at the input terminals of the conversion module and the AC current flowing between the input terminals of the conversion module, by controlling the transistor group (30) of the conversion module and by means of at least one capacitive element (42) of the conversion module.

5. Electrical distribution system (10) according to claim 4, configured to be controlled by the control method of any one of claims 1 to 3, wherein, for each conversion module (20U), the electronic control unit (28) is configured to implement regulation of the DC voltage delivered by the conversion module to the associated electrical load (16) and maintenance of the apparent power of the conversion module equal to the target value.

6. Electrical distribution system (10) according to any one of claims 4 to 5, wherein the transistor group (30) of each conversion module (20U) comprises insulated-gate bipolar transistors.

7. Electrical distribution system (10) according to any one of claims 4 to 6, wherein the plurality of conversion modules (20U) comprises at least ten conversion modules (20U).

8. Electrical distribution system (10) according to any one of claims 4 to 7, wherein each conversion module (20U) further comprises a protection circuit (26) configured to circulate the single-phase alternating current delivered by the power supply device (12) between the input terminals (22) of the conversion module by short-circuiting the transistor group (30) in the event of failure of the conversion module and / or the associated electrical load (16).

9. Electrical distribution system (10) according to any one of claims 4 to 8, wherein the power supply device (12) is configured to deliver a three-phase alternating current and an alternating voltage between 10 kV and 35 kV per phase, the first current corresponding to the first phase of the three-phase alternating current and the first voltage corresponding to the first phase of the three-phase alternating voltage, in which the plurality of conversion modules (20U) forms a first group of conversion modules (20U) in which the electrical distribution system (10) further comprises a second group of conversion modules (20V) and a third group of conversion modules (20W), the conversion modules (20V, 20W) of the second group of conversion modules and of the third group of conversion modules being identical to the conversion modules (20U) of the first group of conversion modules, and each being respectively associated with an electrical load (16), and in which: - the conversion modules (20U) of the first group of conversion modules are connected in series to the power supply device (12) so that the first current flows between the input terminals (22) of all the conversion modules (20U) of the first group and so that the first voltage is applied to all the conversion modules of the first group, - the conversion modules (20V) of the second group of conversion modules are connected in series to the power supply device (12) so that a second single-phase alternating current, corresponding to a second phase of the three-phase alternating current, flows between the input terminals (22) of all the conversion modules (20V) of the second group and so that a second single-phase alternating voltage, corresponding to a second phase of the three-phase alternating voltage, is applied to all the conversion modules of the second group, and - the conversion modules (20W) of the third group of conversion modules are connected in series to the power supply device (12) so that a third current single-phase alternating current, corresponding to a third phase of the three-phase alternating current, flows between the input terminals (22) of all the conversion modules (20W) of the third group and so that a third single-phase alternating voltage, corresponding to a third phase of the three-phase alternating voltage, is applied to all the conversion modules of the third group.

10. Power distribution system (10) according to any one of claims 4 to 9, wherein the power distribution system (10) is a data processing center comprising a plurality of bays (14), each power load (16) and each conversion module (20U, 20V, 20W) being associated with a bay (14), each power load (16) being disposed in the associated bay (14), each conversion module (20U, 20V, 20W) being fixed to the associated bay (14) or integrated into the associated bay.