EP3178128A1

EP3178128A1 - Arrangement and method for the galvanically separated energy transmission

Info

Publication number: EP3178128A1
Application number: EP15760127.9A
Authority: EP
Inventors: Dominik ERGIN; Dennie Lange; Sebastian MARTIUS; Benjamin Sewiolo; Andreas Ziroff
Original assignee: Siemens AG
Current assignee: Siemens Energy Global GmbH and Co KG
Priority date: 2014-09-08
Filing date: 2015-08-31
Publication date: 2017-06-14
Anticipated expiration: 2035-08-31
Also published as: WO2016037881A1; EP3178128B1; CN107078371A; PL3178128T3; US20170324134A1; DE102014217932A1; CN107078371B; US9876263B2; ES2819253T3

Abstract

The invention relates to an arrangement and a method for the galvanically separated energy transmission, in which the energy is transmitted via a dielectric waveguide.

Description

description

Arrangement and method for galvanically separated energy transmission

The invention relates to an arrangement for galvanically separated energy transmission according to the preamble of claim 1, as well as a method for galvanically isolated energy transmission according to the preamble of claim 12.

It is common knowledge that are driven in energy systems and components supplied with energy Müs ^¬ sen. In this case, it must be ensured that system components are insulated against a high-voltage potential, which is why a galvanically separated structure is necessary.

These components may e.g. Switching elements, electronic modules or measuring points, which must be isolated against ground potential. The energy transfer takes place mainly wirelessly, for example via the so-called "Radio Frequency Identification (RFID)" technology or optical fiber.

The received power is well below one watt, mostly in the 10 OmW range. This is due to the fact that the diode-based rectifiers used for this purpose have limitations with regard to current and voltage peaks as well as heat dissipation. For this reason, only the supply of a consumer with low power consumption is possible.

The object of the invention is to provide a method and an arrangement which overcome the disadvantages of the aforementioned solutions. This object is achieved by an arrangement for galvanically separated energy transmission according to the features of claim 1 and by a method for galvanically isolated energy transmission according to the features of claim 12. The arrangement according to the invention for galvanically separated energy transmission with voltages in the high-voltage range is designed in such a way that the energy transmission takes place through a dielectric waveguide. This ensures that the received power, that is the pre-consumer ^¬ scheduled performance, namely up to 10 watts or higher, is significantly higher than the prior art allows. The use of the dielectric waveguide according to the invention also offers the possibility of supplying several consumers in such a way that the power is divided between them. For this purpose, the dielectric waveguide is preferably designed such from ^¬ that it comprises at least a first rectifier device and at least a second rectifying means a functional connection in such a way that the first rectifier means on the input side to a verorteten along the length of the waveguide first Auskop ^¬ pelstelle along the Length of the dielectric waveguide has a conductive connection and the second rectifier ^¬ tereinrichtung input side to a located along the length of the waveguide second decoupling a ^{leit ¬} de compound and the signal input of Wellenlei ^¬ ters and each other have a distance. This thus a decoupling of the transformer ^¬ NEN performance is realized before the end of the dielectric waveguide, as a further degree of freedom, wherein the second coupling-out or egg ^¬ ne any further extraction location can be arranged with rectifying means Rich ^¬ tung at the end. Due to the different distances, the division of the power is generated, which is then passed through the rectifier device to the respective consumer.

If one wants to realize a 1: n division of power, where n is the number of consumers / decoupling points, it is therefore advantageous if the arrangement is developed such that the configuration of the decoupling of the first decoupling point and / or the distance of the first decoupling point to the signal - input of the waveguide and the configuration of Auskopp ^¬ ment of the first coupling-out point and / or the distance of the first coupling-out point to the signal input of the waveguide of ^¬ art are designed differently to each other that the value of a ner taken at the first and second outcoupling power is the same.

Advantageous embodiments are obtained if, in a development in which the functional connection is designed as holes located at a distance for coupling out power configured holes, slots and / or attached to the decoupling conductor ^¬ structures. These configurations are in particular ^¬ special for the mentioned variation of the coupling particularly suitable.

By a further development such that the dielectric waveguide at least one electrically insulating shield device is arranged, the creep ^¬ distance so-called, so the path from caused usually of environmental influences, in particular on the surface of Dielektri ^¬ Kums extending, electric currents prolongs and thereby minimize the loss.

For example, to ten small to HAL the dimension of the array, the training can, in such a way that the insulating From ^¬ schirmungseinrichtung is designed such that its dielectric constant is smaller than the dielectric ^¬ constant of the dielectric waveguide and is mounted directly on the waveguide, preferably be used. The low dielectric constant ensured here that the directly attached to shield means does not, at least not disturbing influences the egg ^¬ properties of the dielectric waveguide. Alternatively, it may be advantageous to further develop the invention such that the insulating shield device is arranged such that a space between the dielectric -Create Wel ^¬ lenleiter and the shield means the distance exists. This will be particularly advantageous if the dielectric constant of the shielding device is greater than or equal to the dielectric constant of the dielectric waveguide.

Alternatively or additionally, it is advantageous to further develop the invention such that this space is filled with particular egg ^¬ nem solid, liquid or gaseous insulating medium, in particular having a dielectric constant that is lower than the dielectric constant of the dielectric waves ^¬ conductor, as in the rule room will be available and a corresponding filling can be used advantageously in the rule. For example, because it as well as the other developments provides additional degrees of freedom for setting an optimal behavior of the transmission.

Preferably, the waveguide is formed from at least one square and / or round, rod-shaped body. This is advantageous, for example, since it is well researched and thus easy to model with regard to optimum function, in particular transmission values.

In order to realize data transmission, such as transmission of timing information, for example, in addition to the transmission of the energy or provision of electrical power, it is advantageous to provide the development in which the arrangement is designed such that at one end of the dielectric waveguide a so-called, in particular as a coaxial cable or microstrip ausge ^¬ stalteter, waveguide transition is functionally connected.

In order for the transmission to take place at high frequency and to produce its effect according to the invention, in particular in the high-voltage range, it will be advantageous to further develop the invention such that the dielectric waveguide is formed from materials, in particular aluminum oxide or Teflon, with a dielectric constant> 1. Through this Finally, training also ensures that the efficiency of energy transmission is further increased, since radiation, ie unwanted power loss, is reduced.

In the method according to the invention for galvanically separated energy transmission with voltages in the high-voltage range, the energy is transmitted via a dielectric waveguide. The inventive method sets by its features the basis for the development of the advantages of the erfindungsge ^¬ Permitted arrangement and its developments.

The invention and further advantages will be explained in more detail with reference to the embodiments illustrated in the figures. It shows the

Figure 1 as exemplary embodiments of the invention Substituted ^¬ staltungen of the dielectric waveguide,

FIG. 2 shows a simplified circuit representation of an exemplary embodiment of the invention in a preferred field of use,

Figure 3 as embodiments two variants for a

Output arrangement according to embodiments of the invention,

4 shows as an exemplary embodiment two variants of the Longer side ^¬ delay of the leakage path in accordance with further developments of the invention.

FIG. 1 shows two of the possible configurations of the dielectric conductor. A first Ausführungsvari ^¬ ante CYLINDRICAL and a second variant

RECTANGULAR are both rod-shaped in the length drawn solid body ^¬ , wherein the first embodiment variant CYLINDRICAL has a round cross-section, while the second Ausfüh ^¬ tion variant has a rectangular cross-section. The shown rod-shaped solid body CYLINDRICAL and RECTANGULAR can also be formed by stringing together to form a longer overall construct.

FIG. 2 shows a simplified circuit diagram of an exemplary embodiment of the arrangement according to the invention, which also reproduces an exemplary embodiment of the method according to the invention.

Evident is an energy transmission arrangement in a high voltage (high voltage, HV) system which, starting from a high frequency signal generator HF_SIGNAL_GENERATOR via a high frequency amplifier HF_VERSTÄRKER using a dielectric waveguide DIELEKTRI SCHER_WELLENLEI ER, the galvanic isolation and transmission of energy to a rectifier device RECTIFIER provides such that the transmitted energy per waveguide rectification is subjected, so that the rectifying device rectified, that is present as a DC clamping voltage ^¬, a voltage at a high-voltage power device (HV line) adjacent terminal tERMINAL available removable.

In order to keep the efficiency of the electronic components as high as possible and due to regulatory conditions regarding the dispersion behavior, the illustrated Ausführungsbei ^¬ game be developed such that the frequencies of the high frequency signal in the ISM band 2.45 GHz and 5.8 GHz are located. Furthermore, it is advantageous to use a material with a low tan δ in such a frame of the transmission frequency for efficient energy transmission.

In order to keep the waveguide DIELEKTRI SCHER_WELLENLEITER as compact as possible and to minimize the radiation, the dielectric constant s _{r is set} as high as possible. Example ^¬ materials, with which this development of the invention is achieved, are aluminum oxide or Teflon. In the example shown it becomes clear that it is possible by the invention to transmit energy through a waveguide instead of through several independent optical waveguides. In this case, the dielectric waveguide DIELEKTRI SCHER_WELLENLEI ER shown in the exemplary embodiment has the property of supplying not only one consumer ENDGER, but several, since, according to the invention, power can already be coupled out before the end of the conductor and fed to another consumer.

In addition, this arrangement has the property that not only an energy required for switching can be transmitted, but also data such as Zeitinforma ^¬ tion, since this is the high-frequency electrical signals of the RF source HF_SIGNAL_GENERATOR can be used.

This is just possible since the illustrated dielectric Wel ^¬ lenleiter is used according to the invention, in which it lenbereich in a round or square (see FIG. 1) rod-shaped material performed with electromagnetic waves of high frequency magnetic ^¬ in the mm-wave or microwave- a Dielektrizitätskons ^¬ aunt> 1 leads.

Thus, this bar both power and a communication signal, for example, can transmit the timing signal at the same time via the electromagnetic wave, the rod via a so-called. Waveguide transition SHAFT guide coupling is Example ^¬ example via a coaxial cable also microstrip line or similar this function Providing facilities to the frequency generator (signal source)

HF_SIGNAL_GENERATOR with suitably selected and modulable output power of frequency generator HF_SIGNAL_GENERATOR connected. FIG. 3 shows embodiments according to the invention shown on an excerpt from the preceding illustration, which result as a further advantage of the dielectric waveguide DIELEKTRI SCHER_WELLENLEITER and lie therein. that the dielectric waveguide DIELECTRIC WAVEGUIDE can technically not only play out its conductor property between its two end points, but that it can also be used to transmit it one-to-one with only a single conductor.

This can be carried out so that the signal from the waves ^¬ conductor via holes as it comprises the dielectric waveguide DIELEKTRI SCHER_WELLENLEITER on the right side, or slots, as the dielectric waveguide

DIELEKTRI SCHER_WELLENLEITER has on the left side of the figure, removed and fed via a rectifier device RECTIFIER to the respective consumer or in the simplest case without the material of the waveguide DIELEKTRI SCHER_WELLENLEITER to structure, in conjunction with metallic conductor structures, can be coupled.

These field outcouplings located at various points on the DIELEKTRI SCHER_WELLENLEITER dielectric waveguide may be at different electrical potential and are due to the dielectric waveguide's insulating properties

DIELEKTRI SCHER_WELLENLEITER (equal) voltage decoupled from each other. The potential differences occurring in principle can be very large and can be achieved by design measures even under conditions of use.

Due to the presence of several decoupling points along the waveguide DIELEKTRI SCHER_WELLENLEITER, the energy transported in the waveguide DIELEKTRI SCHER_WELLENLEITER decreases according to the decoupled power. For this purpose, a development of the invention, the weaker from the wave feed (in the figure 3 with the arrows) hereafter considered first output to perform later than the following (represented by the smaller dimension of the slot or the opening), for example to realize that at all decoupling points the removed Performance is the same value if desired. For example, for each outcoupling point 1 watt (W) could be taken at a total signal power of 3 W, so that the first coupling, for example in the ratio of the dimension to each other 1/3, the second 1/2 and the third 1 should be.

This possibility is given in waveguide transitions and Auskopp ^¬ lungs according to the invention in general and can be regarded together with the possibility of multiple outcouplings as a significant advantage of the illustrated embodiment.

Finally, FIG. 4 shows embodiments which further develop the invention in such a way that they lengthen the so-called creepage distance between HV potential and GND potential (see FIG.

For example, there is the option of providing the waveguide with umbrellas. That for example, to be sheathed by an insulator. This variant can be seen in the figure 4 on the left side. This shielding

HIGH VOLTAGE_I SOLATOR can, if the s _{r of} the insulator

HIGH VOLTAGE_I SOLATOR is small compared to that of the waveguide DIELEKTRI SCHER_WELLENLEITER and therefore the properties are not affected, directly at the waveguide

DIELEKTRI SCHER_WELLENLEITER (not shown) may be appropriate. If the screen HIGH VOLTAGE_I SOLATOR as Darge ^¬ represents is located at a certain distance. Since the pipe diameter is larger than the diameter of the waveguide

DIELEKTRI SCHER_WELLENLEITER, in this space generated by the distance generally a solid, liquid or gaseous insulating medium can be introduced in such a way that the properties of the waveguide

DIELEKTRI SCHER_WELLENLEITER, which conduct electromagnetic wave in the dielectric, is not affected, but rather the transmission is even optimized. The indicated in the figure 4 on the right side meander structure of the dielectric waveguide

DIELEKTRI SCHER_WELLENLEI ER extends the path of the creepage path by shaping the waveguide

DIELEKTRI SCHER_WELLENLEI ER and can therefore do without insulator HOCHSPANNUNGS_I SOLATOR.

The invention is not limited to the Ausführungsbeispie ^¬ le shown, but rather comprises all of the claims covered embodiments, which use a dielectric waveguide for energy transmission in high-voltage systems (HV environment) instead of an opti ^¬ cal fiber and, inter alia, the beneficial effects unfolded

• that one or more decoupling points of the dielectric

Waveguide for the simultaneous removal of Informati ^¬ one (for example, timing signals) at different locations and similar or different services at different potentials are possible, and further improvements of this approach of using the dielekt ^¬ step waveguide for information and / or Leis ^¬ tung transmission in HV environment due to shielding and / or meander structure can be used to generate microwave power in the range of a few watts and this with low hardware costs, which also applies to the transmission of the power with the dielectric conductor,

• further has the advantage that tolerance requirements are relaxed in the assembly of corresponding components and also the denomination of a dielectric waveguide of single bars shorter length is easily possible and does not require sophisticated joining tolerances,

• that the waveguides are also inexpensive if they are manufactured by plastic injection molding or extrusion. If they are made of ceramics, eg aluminum oxide, Manufactured, the waveguide can be used at the same time for the Entwärmen of circuit parts, as well as given that redundancy concepts are realized very easily, for example, if necessary, two or more n high-frequency sources on the source side simultaneously on the waveguide and / or outcoupling if necessary, two or more more independent coupler can be realized, all of which remove the required operating power and the timing signal independently from the Wel ^¬ lenleiter.

Claims

claims

Arrangement for galvanically separated energy transmission with voltages in the high-voltage range, designed such that the energy transfer takes place through a dielectric waveguide.

Arrangement configured such that the dielectric waveguide with at least one first rectifier device and at least one second rectifier device has a functional connection ^¬ such that the first rectifier device on the input side to a along the length of Wellenlei ^¬ ters located first outcoupling along the length of the dielectric Waveguide has a conductive Ver ^¬ bond and the second rectifier device has a lei ^¬ tende connection on the input side to a located along the length of Wel ^¬ lenleiters second coupling point and the signal input of the waveguide and each other at a distance.

Arrangement according to claim 2, characterized in that the embodiment of the decoupling of the first decoupling point to and / or the distance of the first Auskoppel ^{¬ point} to the signal input of the waveguide and the ^¬ design of the decoupling of the first decoupling point and / or the distance of the first decoupling point to Signal input of the waveguide are so varied designed to each other that the value of one taken at the ers ^¬ th and second coupling point power is the same.

Arrangement according to one of the two preceding claims, characterized in that the functional Ver ^¬ bond as spatially located at the distance designed for coupling out power holes, slots and / or attached to the coupling-out conductor structures are ^{ausgebil ¬} det.

5. Arrangement according to one of the preceding claims, characterized in that the dielectric Wellenlei ^¬ ter at least one electrically insulating shielding device is arranged.

6. Arrangement according to the preceding claim, characterized in that the insulating Abschirmungseinrich ^¬ device is designed such that its Dielektrizi- tätskonstante is smaller than the Dielektrizitätskons ^¬ tante of the dielectric waveguide and is mounted directly on the waveguide.

7. Arrangement according to one of claims 1 to 5, character- ized in that the insulating Abschirmungseinrich ^¬ device is arranged such that there is space generating distance between the dielectric waveguide ^¬ and the shield.

8. Arrangement according to the preceding claim, characterized in that this space is filled with, in particular a solid, liquid or gaseous, insulating medium, in particular with a dielectric constant which is lower than the dielectric constant of the dielectric waveguide.

9. Arrangement according to one of the preceding claims, characterized in that the waveguide from mindes ^¬ least as a, in particular angular and / or round, rod-shaped body is formed.

10. Arrangement according to one of the preceding claims, characterized in that at one end of the dielectric ^¬ 's waveguide so-called, in particular as coaxial cable or microstrip ausgestalteter,

Waveguide transition is functionally connected.

11. Arrangement according to one of the preceding claims, characterized in that the dielectric Wellenlei ^¬ ter of materials, in particular aluminum oxide or Teflon, with a dielectric constant> 1 is formed.

12. A method for galvanically isolated energy transmission, with voltages in the high-voltage range, designed such that the energy is transmitted via a dielectric waveguide.