DE102012213055A1 - Device for galvanic insulated distribution of electrical power, supplies power to primary winding of cascade in subsequent inductive loop coupling element through secondary winding of cascade in other inductive loop coupling element - Google Patents

Abstract

The device has inductive loop coupling elements (21,22) that are provided with magnetic circuits (6i) comprising a common primary winding (31). Each magnetic circuit is provided with a secondary winding (32). The primary winding of the cascade in the subsequent inductive loop coupling element (22) is supplied with energy through the secondary winding of the cascade in the preceding inductive loop coupling element (21). An independent claim is included for a method for galvanic insulated distribution of electrical power.

Description

The invention relates to a device for the galvanically isolated distribution of electrical energy.

Moreover, the invention relates to a method for the galvanically isolated distribution of electrical energy.

In power engineering devices of high voltage engineering often electromechanical and electronic assemblies are operated at a high voltage potential, which must be constantly supplied with energy for correct operation. This is especially true for switching devices in the medium and high voltage technology and especially for devices of high voltage direct current (HVDC). In this case, assemblies, electronic submodules and / or electromechanical submodules must be supplied with power to potentials up to the megavolt range. At the same time (especially with transient switching voltages and load with lightning impulse voltage) a high interference voltage level has to be considered. In accordance with the state of the art, electrical components (or their combinations) are usually used whose dielectric strength corresponds to only a fraction of the expected voltage load. Therefore, the components are usually integrated into so-called submodules, which are connected in series in a corresponding number in order to achieve a required dielectric strength. Especially with submodules of the HVDC technique, high power is provided at times at a high voltage potential, for example when charging capacitors of submodules. In addition, when using semiconductor switches electronic components (for example, of thyristors or bipolar transistors such as IGBT) whose drive units must be constantly supplied with electrical energy to allow in any operating condition a secure operation (IGBT = insulated gate bipolar transistor).

• – kapazitive Spannungsteiler,
• – induktive Kopplung (Transformatoren),
• – ohmsche Kopplung / Spannungsteiler,
• – optische Energieübertragung mit Lasern,
• – induktive Versorgung mehrerer Stufen mittels eines mittelfrequenten Umrichters und einer hochspannungsisolierten Induktionsschleife als Primärwindung mehrerer Transformatoren.

The following concepts are known for this:

• - capacitive voltage dividers,
• - inductive coupling (transformers),
• Ohmic coupling / voltage divider,
• - optical energy transmission with lasers,
• - Inductive supply of several stages by means of a medium-frequency converter and a high-voltage insulated induction loop as a primary winding of multiple transformers.

The first three concepts in particular have the disadvantage that transient disturbances in the form of transient switching voltages or lightning impulse loads are capacitively coupled into the energy transmission system. These concepts can therefore only limited or at the cost of a very high cost (isolation, shielding, power dissipation) fulfill the required functions. The fourth concept is not suitable for transmitting higher powers than a few watts at the most, so that it is too low-performance and too expensive for many high-voltage engineering tasks.

The latter method is in US 2012/0032512 A1 described. Here, a series circuit of primary windings of several high-voltage current transformers is supplied from a regulated AC power source (for example, 20 kHz), at the secondary windings each a power supply for each control of another M2LC subsystem is connected (M2LC = modular multilevel converter). This power distribution technique is known in the art as 'induction loop coupling' (ISK) and has been used by the company 'Dairyland Electrical Industries', for example, for the operation of so-called 'DC blocking devices' (DCBD). DCBD were used to ground a transformer neutral point DC decoupled. The ISK process is currently used for applications up to a few 10 kV, with an isolation level of typically around 40 to 50 kV maximum.

The known device for the galvanically isolated transmission of electrical energy has the disadvantage that the insulation requirements for the primary winding to be isolated (induction loop) at overlying voltages are so great that the coupling factor for economical use of the inductive coupling is too low. In addition, at higher voltages inevitably increases a coupling of transient disturbances in the power supply unit, so that it no longer works correctly or is damaged in transient voltages occurring as switching or lightning surges.

The invention has for its object to provide a device for galvanically isolated distribution of electrical energy, which is also suitable for supplying the controls of submodules of a high voltage DC switch for several 320 kV nominal voltage and an expected surge voltage load with an amplitude of about 750 kV. Here, assemblies or modules that are at a high voltage potential (i.e., operated) can be supplied with sufficient power reliably, permanently, and with the least possible loss and spurious signal interference.

According to the invention the object is achieved in that a device for the galvanically isolated distribution of electrical energy comprising at least two magnetic circuits having a common primary winding and each of the magnetic circuits having at least one secondary winding; wherein the primary winding of each subsequent in the cascade induction loop coupling via a secondary winding of a respective preceding in the cascade induction loop coupling with energy can be supplied.

With respect to the process for the galvanically isolated distribution of electrical energy, the object is achieved in that the method comprises the following steps:
- impressing an alternating current into a preceding induction loop coupling;
- withdrawing electrical energy from the preceding induction loop coupling for a first set of electrical consumers by means of a respective consumer-specific secondary winding of the preceding induction loop coupling;
characterized in that
the method additionally comprises the following steps:
Extracting electrical energy from the previous loop inductor for subsequent induction loop coupling by means of a secondary winding of the preceding loop inductor;
Feeding the electrical energy removed for the subsequent induction loop coupling to the subsequent induction loop coupling;
- Removing electrical energy from the subsequent induction loop coupling for a second set of electrical loads by means of a consumer-specific secondary winding of the subsequent induction loop coupling.

By means of a cascading of induction loop couplings by means of pairwise coupling of the induction loop couplings via magnetic circuits, a high voltage potential difference of, for example, several 100 kV can be distributed over a plurality of induction loop couplings.

It is expedient if the primary winding of the directly following in the cascade induction loop coupling by means of a secondary winding of the directly preceding in the cascade induction loop coupling with energy can be supplied. As a result, predetermined total voltage potential can be covered with a minimum of induction loop couplings of predetermined dielectric strength.

It may be advantageous if a similar consumer can be connected to the secondary winding, by means of which the primary winding of the subsequent induction loop coupling can be supplied, as it can be connected to at least one secondary winding of one of the other magnetic circuits of the induction loop couplings. As a result, space and effort for a current transformer can be largely saved per induction loop coupling.

One embodiment provides that the common primary winding of the subsequent induction loop coupling with the secondary winding of the preceding induction loop coupling, by means of which it can be supplied with energy, forms a common circuit. As a result, a low-loss transmission of electrical energy from the preceding induction loop coupling for subsequent induction loop coupling is possible.

A further embodiment provides that a potential separation is arranged between the common primary winding of the subsequent induction loop coupling and the secondary winding of the preceding induction loop coupling, by means of which the common primary winding of the subsequent induction loop coupling can be supplied with energy. In this way, an additional dielectric strength of the device according to the invention can be achieved.

In particular, it may be preferred that the potential separation comprises a magnetic intermediate circuit. As a result, with a given number of induction loop couplings, a dielectric strength of the device for distributing electrical energy can be improved.

It may also be advantageous if at least one of the magnetic circuits comprises a potential separation. As a result, a further improvement in the dielectric strength of the device for distributing electrical energy can be achieved.

In particular, it is preferable if a performance of the respective primary circuit and / or the respective secondary circuit and / or the magnetic intermediate circuit, by means of which the common primary winding of each subsequent induction loop coupling can be supplied with energy from the secondary winding of the preceding induction loop coupling, a sum of the power requirements of all the cascade subsequent induction loop couplings covers, the performance of this power requirement by not more than 50%, more preferably not more than 20%, exceeded. As a result, an expenditure on equipment (for example, production costs, space requirements) for each subsequent induction loop couplings is less than for respective preceding induction loop couplings. By this measure is thus a Total cost of production of the system for the galvanic separation of electrical energy reduced.

The invention is explained in more detail with reference to the accompanying drawings, in which:

1 schematically a first embodiment of a high-voltage device having a plurality of sub-modules whose controls are supplied by means of a device according to the invention with electrical energy;

2 schematically a second embodiment of a high voltage device having a plurality of submodules, whose controls are supplied by means of a device according to the invention with electrical energy, wherein the device for the galvanically isolated distribution of electrical energy comprises an additional galvanic isolation;

3 schematically a method for galvanically isolated distribution of electrical energy.

The embodiments described in more detail below represent preferred embodiments of the present invention.

This in 1 illustrated system 10 comprises a high-voltage device (for example, a MMC modules, MMC = modular multilevel converter), which is a series circuit of a plurality of (preferably identical) submodules 1i having. In addition, the system includes 10 two induction loop couplings 21 . 22 ,

The primary winding 31 each of the two induction loop couplings 21 . 22 typically comprises only one turn, this turn being through the entire primary circuit 41 is formed. The primary winding 31 the previous induction loop coupling 21 is at a first regulated AC source 51 connected. The primary circuit 31 encloses a plurality of (preferably equally spaced) toroidal cores 6i , The ring cores 6i represent magnetic circuits, which in 1 and 2 are shown in dashed lines. To distinguish circuits in the figures are shown by a solid line.

On an opposite side of each ring core 6i is each a secondary winding 32 arranged with several turns. At each of the secondary windings 32 In each case, a power supply part is connected to a respective control of one of the submodules 1i to supply with electrical energy.

To supply the following induction loop coupling 22 with electrical energy is the primary winding 31 the subsequent induction loop coupling 22 to a second regulated AC source 52 connected. The second regulated AC source 52 is over the last ring core 6i in the row of ring cores 6i the previous induction loop coupling 21 supplied with electrical energy.

This is the second regulated AC power source 52 at a secondary winding 32 connected on the last ring core 6i is arranged.

By means of the concept according to the invention, an energy distribution (almost unlimited scalability) up to voltage levels of several 100 kV is practicable. The concept is suitable for voltage levels which are many times higher than the voltage level of about 40 kV which is practicable by means of the known induction loop coupling. This is made possible by individual electronic or electromechanical assemblies 1i with voltage strengths of a few kilovolts by means of series connection to modules 2i whose dielectric strength is some 10 kV, typically about 20 to 40 kV, and the modules 2i each of an induction loop coupling 21 be supplied. These modules 2i are in turn connected in series to achieve a required total voltage resistance for a total voltage Ug. In this case, according to the invention, the induction loop couplings 21 . 22 cascades, so that at no point in the system potential differences of more than, for example 40 kV occur.

In order for the AC power source 52 the subsequent induction loop coupling 22 a higher performance than for a single submodule 1i can provide the toroidal core 6i , about which the subsequent induction loop coupling 22 is powered with a larger cross-section than the other ring cores 6i the previous induction loop coupling 21 , Alternatively or additionally, the secondary winding 32 , about which the subsequent induction loop coupling 22 is supplied with a larger number of turns than the other secondary windings 32 the previous induction loop coupling 21 ,

Optionally, in addition, a galvanic isolation 91 in the AC power source 52 be provided. This is the primary circuit 41 the subsequent induction loop coupling 22 to the secondary winding 32 of the preceding induction loop coupling 21 , from which the following induction loop coupling 22 is supplied with electrical energy, galvanically isolated.

The cascading of the induction loop couplings 21 . 22 causes the topmost module 2i (the one at the highest potential) from the associated induction loop coupling 22 Requires the lowest power consumption, while the potential lower (previous) induction loop couplings 21 constantly provide higher levels of performance, since they are the overlying (subsequent) modules 2i including the power loss generated there must supply.

It is thus expedient if the first induction loop coupling 21 must provide more than n times the performance if n modules 2i be connected in series. The modules above 2i each have to provide correspondingly less power (n-1-fold, n-2-fold and so on). This modular design means that high efficiency is achieved in all stages and system power loss is minimized. At the same time, the crosstalk of transient disturbances is limited to the technically controlled level of a few 10 kV, so that requirements with regard to transient surges can also be met with the overall system.

It is particularly advantageous if the induction loop couplings 21 . 22 not just for the required performance of a module 2i (or inductor coupling stage), but when multiple smaller loop inductor couplings are used in parallel, their overall performance is eliminated with the elimination of a single (or a few) induction loop coupling 21 is still sufficient to all over it modules 2i to supply. Due to this modular design, it can be achieved that even in the event of a failure of a single preceding induction loop coupling 21 the whole system 10 sure to continue working. About a corresponding (preferably electrically isolated, for example, optical) communication system, the individual induction loop couplings 21 . 22 not only be controlled or synchronized, but also monitored at the same time, so that the failure of individual induction loop couplings 21 . 22 is reported to facilitate a targeted exchange of information during routine system maintenance.

The 2 shows a second embodiment of a high voltage device 10 for galvanically isolated distribution of electrical energy with additional galvanic separations 92 , The additional galvanic isolation 92 here is that the ring cores 6i in the form of two half-rings are constructed in two parts, wherein the toroidal cores 6i two toroidal gaps each 65 between each of which an insulating material 66 is inserted.

This in 3 shown method 100 for the galvanically isolated distribution of electrical energy comprises the following steps. In a first step 110 An alternating current I ' _{AC is converted} into a preceding induction loop coupling 21 imprinted. In a second step, electrical energy from the preceding induction loop coupling 21 for a first quantity of electrical consumers 1i by means of one secondary winding each 32 the previous induction loop coupling 21 taken. In a third step 130 becomes electrical energy from the preceding induction loop coupling 21 for a subsequent induction loop coupling 22 by means of a secondary winding 32 the previous induction loop coupling 21 taken. In a fourth step 140 becomes the for the subsequent induction loop coupling 22 removed electrical energy of the subsequent induction loop coupling 22 fed. In a fifth step, electrical energy from the subsequent induction loop coupling 22 for a second amount of electrical consumers 1i by means of one secondary winding each 32 the subsequent induction loop coupling 22 taken.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 2012/0032512 A1 [0006]

Claims (9)

Contraption ( 11 ) for the galvanically isolated distribution of electrical energy, characterized in that the device ( 11 ) a cascade of at least two induction loop couplings ( 21 . 22 . 23 ); wherein each of the induction loop couplings ( 21 . 22 . 23 ) at least two magnetic circuits ( 6i ) with a common primary winding ( 31 ) and each of the magnetic circuits ( 6i ) at least one secondary winding ( 32 ) having; where the primary winding ( 31 ) of the respective subsequent in the cascade induction loop coupling ( 22 . 23 ) via a secondary winding ( 32 ) of an induction loop coupling in each case in the cascade ( 21 ) is supplied with energy. Contraption ( 11 ) according to the preceding claim, characterized in that a primary winding ( 31 ) of the directly following in the cascade induction loop coupling ( 22 ) by means of a secondary winding ( 32 ) of the induction loop coupling directly preceded in the cascade ( 21 ) is supplied with energy. Contraption ( 11 ) according to one of the preceding claims, characterized in that on the secondary winding ( 32 ), by means of which the primary winding ( 31 ) of the subsequent induction loop coupling ( 22 ), is a like consumer ( 1i ), as it is connected to at least one secondary winding ( 32 ) one of the other magnetic circuits ( 6i ) of the induction loop couplings ( 21 . 22 ) is connectable. Contraption ( 11 ) according to one of the preceding claims, characterized in that the common primary winding ( 31 ) of the subsequent induction loop coupling ( 22 ) with the secondary winding ( 32 ) of the preceding induction loop coupling ( 21 ), by means of which it can be supplied with energy, a common circuit ( 41 ). Contraption ( 11 ) according to one of the preceding claims, characterized in that between the common primary winding ( 31 ) of the subsequent induction loop coupling ( 22 ) and the secondary winding ( 32 ) of the preceding induction loop coupling ( 31 ), by means of which the common primary winding ( 32 ) of the subsequent induction loop coupling ( 22 ) can be supplied with energy, a potential separation ( 91 . 92 ) is arranged. Contraption ( 11 ) according to the preceding claim, characterized in that the potential separation ( 91 ) a magnetic intermediate circuit ( 70 ). Contraption ( 11 ) according to one of the preceding claims, characterized in that at least one of the magnetic circuits ( 6i ) a potential separation ( 92 ). Contraption ( 11 ) according to one of the preceding claims, characterized in that a performance of the respective primary circuit ( 41 ) and / or the respective secondary circuit and / or the magnetic intermediate circuit ( 70 ), by means of which the common primary winding ( 31 ) of the respective subsequent induction loop coupling ( 22 ) with energy from the secondary winding ( 32 ) of the preceding induction loop coupling ( 21 ), a sum of the power requirements of all subsequent in the cascade induction loop couplings ( 22 ), the performance exceeding this power requirement by not more than 50%, particularly preferably not more than 20%. Procedure ( 100 ) for the galvanically isolated distribution of electrical energy, wherein the method ( 100 ) following steps ( 110 . 120 ) comprises: - memorizing ( 110 ) of an alternating current (I ' _AC ) into a preceding induction loop coupling ( 21 ); - Remove ( 120 ) of electrical energy from the preceding induction loop coupling ( 21 ) for a first quantity of electrical consumers ( 1i ) by means of one consumer-specific secondary winding ( 32 ) of the preceding induction loop coupling ( 21 ); characterized in that the method ( 100 ) additionally the following steps ( 130 . 140 . 150 ) comprises: - removing ( 130 ) of electrical energy from the preceding induction loop coupling ( 21 ) for a subsequent induction loop coupling ( 22 ) by means of a secondary winding ( 32 ) of the preceding induction loop coupling ( 21 ); - Respectively ( 140 ) for the subsequent induction loop coupling ( 22 ) removed electrical energy to the subsequent induction loop coupling ( 22 ); - Remove ( 150 ) of electrical energy from the subsequent induction loop coupling ( 22 ) for a second quantity of electrical consumers ( 1i ) by means of one consumer-specific secondary winding ( 32 ) of the subsequent induction loop coupling ( 22 ).

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