WO2018069424A1 - Communication system in a current supply grid - Google Patents

Abstract

The invention relates to a communication system in a current supply grid, having at least one controller and at least one current conversion device. The current supply grid is simultaneously used for communication between the at least one current conversion device and the controller. The voltage is modulated for the communication between the at least one power conversion device and the controller, wherein the modulated current signal is superimposed over a current to/from the current conversion device, and the modulation is implemented by a device selected from the group having a power factor correction device and an inverter.

Description

 COMMUNICATION SYSTEM IN A POWER SUPPLY NETWORK

TU Dortmund, Germany

The invention relates to a communication system.

background

Control systems in smart home and smart grid applications include a variety of tasks. They may include simple lighting controls to enhance comfort, but also more complex energy management systems to avoid overloading individual line outlets or transformer stations, to the integration of storage systems to provide network services.

For example, for communication between the electric vehicle and the charging station, communication via ISO 151 18 and IEC 61851 is proposed. To connect the charging station to backend systems, Open Charge Point Protocol (OCPP) is proposed. The local network stations are usually not connected. In some cases, station buses with IEC 61850 are used.

On the other hand, connection of smart meter gateways will be discussed. Here, the Smart Meter Gateway is to provide an interface with which local switchable devices (CLS) can be controlled. However, the more precise design of the channel remains open, especially with regard to the identification of switchable loads.

However, due to proprietary protocols and / or due to the particular system approach, the previous systems are unable to provide the required level of communication in a simple and cost-effective manner. In this respect, only a large number of partial solutions are offered, but they do not consider the entire system of a power supply.

This is illustrated by the example of a charging infrastructure.

A form of communication between the vehicle and the charging station is defined in the IEC61851 and IS0151 18 protocols. A connection to backend systems or smart meter systems, however, is not defined.

There are proprietary solutions for connecting backend systems as well as open standards such as OCPP.

A secure connection of smart meters is not yet done. The energy meter is thus unable to allocate the consumption of a stored mobile consumer to this. The assignment must be made via a separate module.

In addition, the previously proposed systems have considerable installation costs. Charging stations must be installed and also connected by communication technology. For example, currently costs of EUR 10000 for a public 22 kW charging point are estimated. Even in the private sector, costs of more than EUR 2200 are currently expected.

A connection of energy and bottleneck management systems at the local network station level and building level has hitherto at best been proprietary.

In addition, previous systems often provide proprietary electro-mechanical interfaces, so that a new costly infrastructure would be necessary because previous power connections such as Schuko sockets or CEE sockets, can not be used because they can not communicate with energy management and billing systems so far. Authorization of the loading process so far takes place via the manual input of IDs at charging points, via the scanning of a QR code with a smartphone app, the use of transponder cards or the direct payment via credit cards. All methods have in common that they are awkward.

Due to the lack of cross-system coupling to controllers it is very difficult or even impossible to build a staggered bottleneck management with the previous systems, which considers the power consumption both at station level, (building) connection point level and management level and the respective subordinate consumers by "plug ^' n' Play "and controls if necessary.

Based on this situation, it is an object of the invention to provide a communication system that allows easy integration into existing network topologies.

The object is achieved by a device according to claim 1. Further advantageous embodiments are in particular subject of the dependent claims, the description and the figures.

The invention will be explained in more detail with reference to the figures. In these shows:

1 is a schematic representation of a current transformer according to embodiments of the invention,

 2 is a schematic representation of a stream with a message according to embodiments of the invention in time and frequency space,

FIG. 3 PFC circuit extended by a message modulator, FIG.

 4 Block diagram of the message coupling with coupling of the message before magnitude formation,

 Fig. 5 Block diagram of the message coupling with coupling of the message by amount, and

Fig. 6 block diagram of the coupling of a message signal in the measured variables of the feedback of the control loop with compensation of the rectifier modulation. Hereinafter, the invention will be illustrated in more detail with reference to the figure. It should be noted that various aspects are described, which can be used individually or in combination. That is, any aspect may be used with different embodiments of the invention unless explicitly illustrated as a pure alternative.

Furthermore, in the following, for the sake of simplicity, usually only one entity will be referred to. Unless explicitly stated, however, the invention may also have several of the entities concerned. As such, the use of the words "a," "an" and "an" is to be understood merely as an indication that at least one entity is used in a simple embodiment.

As already stated, most previous systems are not networked with each other and require their own communication channels.

The invention allows an improved networking of the participants with each other, so that even cross-system tasks can be managed by decentralized controls. In this case, the invention can be used in particular in a system and method according to the publication DE 10 2014 008 222 A1, which is hereby incorporated explicitly as part of the application.

FIG. 1 shows an example of a power conversion device. It should be noted that power conversion devices according to the invention include both consumers and generators, such as e.g. Inverter, can be. In this respect, the term below always refers to both possibilities, unless explicitly stated otherwise.

The communication system according to the invention is to be understood in relation to a power supply network. In this case, the communication system has at least two communication partners, whereby the term communication is not limited to two-way communication, but also includes the sending of messages in one direction only (unidirectional communication as in DE 10 2014 008 222 A1). The communication system according to the invention has at least one control device and at least one power conversion device.

In this case, the power supply network also serves the communication between the at least one power conversion device and the control unit.

For communication between the at least one power conversion device and the control device, the current is modulated, wherein the modulated current signal is superimposed on a current to / from the power conversion device. If the power conversion device is a consumer, the current between the load and the control device is usually a consumption current. If the power conversion device is a generator, then the current between the power source and the control device is usually a supply current. As far as interference is concerned in this context, there is not necessarily a current flow, i. a supply current or consumption current, necessary between the power conversion device and the control device, i. the current can also be 0 A, in which case only the communication is impressed as current.

The invention makes use of the fact that the power grid is already available as a communication medium. That It does not require expensive reinstallation of communication infrastructure. But this also allows a "plug'n'play" functionality, which offers a low entry threshold, so that the system is user-friendly.

A control message may be generated by a power electronic circuit and provided as a modulated current signal. For this purpose, existing elements can be controlled accordingly. For example, the message can be introduced via a reference variable and / or a feedback variable in an existing control loop.

Among other things, such a staggered bottleneck management can be realized at the local network station level up to individual cable outlets in buildings.

At the local network station level, it is also possible to aggregate and control the storage and load-shifting potentials of individual consumers; within buildings, intelligent home controllers can be set up. The control systems required for this purpose can use the tree structure of the energy networks; by placing them at network nodes, the respective subordinate consumers are managed. A control at the local network station level can manage the system services, while another controller within the building installation can take over the home control and the utilization of individual cable outlets can be monitored by separate controllers.

The control systems in the network nodes may each require a unique identification of the subordinate consumers for coupling.

The approach presented here provides for identification and localization of a subscriber of the communication system via a current-modulated signal (power message) which is fed into the power grid.

For example, immediately after connecting a power converter to the power grid, the power converter sends an (initialization) message, e.g. with coupling information. This (initialization) message may e.g. include a specific network address, a public key for connection protection, device properties, etc.

Preferably, only control systems along the direct path from the CT to the controller receive the message, i. the example of a consumer in the direction of the local network station.

The coupling information can be used eg for a (further) bidirectional control channel via radio or (narrowband) powerline communication (PLC). The device can now become a member of the system controlled by the control device. The subsequent control of the current transformers can take place (exclusively) via the bidirectional channel. In one embodiment of the invention, the modulation of the current is realized by a device selected from the group comprising Power Factor Correction, inverters.

That the generation of the messages, in particular the (initialization) message, can e.g. via the power electronics of the (consumer) devices.

The power electronics in a consumer usually works with active components, such as the charging rectifier in an electric vehicle.

This power electronics is also able to draw or feed a current not equal to the grid frequency from the power grid. The power electronics enable a modulation of the absorbed current.

Although powerline communication systems are similar in structure - In PLC systems, the transmitting unit also couples the message signal into the power grid - however, one crucial difference is the nature of the signal - PLC signals are multi-carrier voltage signals - another difference is the transmit frequency used. The transmit frequency used, which is typically between 150 kHz (narrow band PLC) and 68 MHz in PLC systems, while the frequency of the modulated current signal is 20 kHz and less. Another difference is that PLC systems only evaluate voltage signals, but not current signals.

In this case, the invention makes use of the fact that the network impedance of the power supply network is highly frequency-dependent. For example, in the field of energy transmission (50 Hz), the network impedance is particularly low, with increasing frequency this increases disproportionately.

The unidirectional current message in the communication system according to the invention preferably uses particularly low carrier frequency, approximately in a range of 200 Hz to 3 kHz, since in this range the network impedance is typically in a range of 0.1 -0.5 Ω. In contrast, the line impedance in the frequency range of 150 kHz (narrowband powerline) up to 68 MHz reaches values between 8 Ω and 500 Ω.

That a current signal whose supply frequency is close to the mains frequency (<= 20 kHz) thus ensures only a low voltage drop over the mains impedance. In contrast, injected currents far above the mains frequency (> 20 kHz) generate a comparatively large voltage drop and can even be measurable in the mains voltage over the entire supply range.

Thus, the propagation characteristics depend strongly on the network impedance. The lower the impedance, the smaller the voltage drop of an injected current.

What is desired is a propagation of the current in the direction of the local network station, which is why the impedance should be as low as possible. The lowest impedance value is usually reached at a frequency of 0 Hz. As the frequency increases, so does the impedance.

The exact frequency response depends on the resources, which each have frequency-dependent impedances and may have some resonance points.

By selecting a low carrier frequency, the current message receives a unidirectional propagation characteristic and can essentially only be measured along the path from the transmitting unit in the direction of the local network station (local network transformer).

With the aid of a current transformer, the current message along the current path can be measured. In contrast, in the sub-branches, for example, at a power outlet, the signal of the stream message is not or not easily measured.

That is, in contrast to a PLC system in which communication from one outlet to another outlet in a branched network should be possible, this feature is not supported by the system according to the invention. As a result, only control devices in the communication system according to the invention, which are placed along the current path, can receive the (coupling) information.

This allows one or more control systems to be paired with the consumer. Due to the tree topology of the power grid, only subordinate consumers can be detected in the control systems.

The choice of the carrier frequency of the current message also has a significant influence on the noise immunity, the propagation characteristics and the transmission rate.

The immunity to interference is essentially influenced by the properties of the equipment in the low-voltage network. Consumers and transformers with non-linear characteristics produce harmonics that are at multiples of the fundamental frequency. Particularly pronounced are the odd harmonics, which occur in low orders (v = 3,5,7, ...) particularly significant. Likewise, even harmonics occur even order, which, however, usually have significantly lower amplitudes, as they should occur only by an unacceptable unbalanced power consumption and thus only with defective equipment. The carrier frequencies should therefore not coincide with odd harmonics of the line frequency but use frequencies between two odd harmonics. Particularly suitable as carrier frequencies are harmonics and interharmonics.

However, it may also be harmonics of other resources in these areas, in particular, the frequencies of ripple control systems are to be avoided. More modern systems use frequencies in the range of 1 10 Hz to 500 Hz, but in some cases even frequencies from older systems up to 3 kHz are used. Further causes of interharmonics lie in active switches in converter systems. However, the switching frequencies are usually above the hearing threshold of 20 kHz and thus the most pronounced harmonics. The modulation method used according to the invention uses at least one carrier frequency and the receiver can check whether the carrier signal is present or not and / or evaluate the signal. Likewise, more complex modulation scheme applicable as amplitude, frequency or phase modulations and a combination of the individual modulation methods such as a quadrature amplitude modulation (QAM).

A higher data rate may e.g. be achieved by the use of multiple carrier frequencies and the use of a larger bandwidth, which is not limited to the carrier frequency. For example, a frequency division multiplexing technique may be constructed via Orthogonal Frequency Division Multiplexing (OFDM).

From the influencing variables, the carrier frequency of 630 Hz was chosen by way of example. This is an intermediate harmonic that is not at a ripple control frequency and is therefore inferior to only minor spurs. Since no high demands are placed on the data rate, carrier frequencies below 3 kHz are sufficient. However, higher frequencies can also be used. The propagation characteristics are very favorable for this application, as shown above. It is also possible to use frequencies other than carriers which are within this range and take into account the above-mentioned influences.

The current modulated message can be generated by conventional switched mode power supplies as shown in FIG. 1, which typically include power factor correction (PFC).

The actual goal of this circuit is to generate a sinusoidal current consumption from the grid.

The structure of this circuit can be done by different circuit topologies, which are selected and dimensioned depending on the application and performance class.

PFC circuits in switched-mode power supplies are used in particular for device power ratings from 75 W to meet the normative requirements for harmonic limits (EN 61000-3-2). For special devices (eg LED lamps) limit values exist independently of the power range, so that even at low power levels, PFC circuits are increasingly being used to increase the power factor and reduce the harmonic load.

The PFC circuit receives a sinusoidal function as the default for the current setpoint and converts this on the line side. This is done by a pulse width modulated (PWM) high-frequency control (20 kHz ... 250 kHz) of the switching elements. By means of the reference signal, which is used for the PWM generation, the input current of the circuit can be directly influenced.

The superposition of the higher-frequency message signal can thus be easily integrated. An additional circuit complexity is usually not required.

The principle can be transferred to almost all converter systems which have an implemented current control. Thus, an integration of the method into (photovoltaic) inverters or chargers for electric vehicles is possible without any changes in circuit technology. Only the control must be supplemented by the generation of the current-modulated message and imprinting on the setpoint.

Figure 1 shows schematically the implementation of the message generation in a cascaded control loop. The circuit-based basis represents an initially arbitrarily constructed PFC topology, in which the switch can be addressed directly via the PWM control of the network-side input current profile of the circuit.

The mains voltage UAC, the line current c and the output voltage of the circuit UDC, which usually represents the controlled variable, are detected by measurement. The manipulated variable represents the PWM function, via which the input current of the circuit can be controlled directly. Because of this relationship, power electronic circuits are usually implemented with current regulation as a fast inner loop. This can be superimposed on any controller, such as an output voltage control.

In the example shown in FIG. 1, the reference variable of the current regulator is formed by two functions. The standardized mains voltage | UAC | is used to generate a desired current waveform which is sinusoidal and in phase with the mains voltage.

This curve is additionally weighted with the output of the voltage regulator to obtain the amplitude of the current consumption. The voltage regulator compares the output voltage with the default and adjusts the amplitude of the current set by the subordinate current regulator accordingly. By adapting this current regulation, the additional generation of the current-modulated message can be supplemented (dashed marked region in FIG. 1).

Only the (additional) current, which represents the current-modulated message, has to be impressed on the scaled desired current profile. The command value of the current controller then consists of the addition of the 50 Hz component, which is used for the active power transmission, and the 630 Hz component of the current-modulated message.

It should be noted that other techniques are not excluded thereby. In particular, the coupling of the current message can also take place via the U-regulating circuit or the measuring circuit of U and I sensors.

FIG. 2 shows the input current profile and the associated spectrum of a typical bidirectional PFC circuit (bridge circuit) with exclusively adapted control for generating the current-modulated messages. Both over time and in the spectrum, the impressed 630 Hz component can be clearly recognized.

In Figure 3, the extended control loop of the PFC is shown. This supplements a usual control circuit, which will be explained first. The voltage regulation gets a predetermined reference value I cret for the DC output voltage UDC The actual quantity UDC is measured and from the difference of the two variables, a control deviation eu can be determined. The measurement of I cret can be filtered via a low pass TP to smooth the voltage ripple of the output voltage. The control deviation eu can furthermore be supplied to a proportional-term integrator.

The tracking of the sinusoidal mains voltage UN takes place in the current controller. For this purpose, the phase position Θ of the mains voltage can be determined via a phase locked loop (PLL) and added to the current reference value f via a multiplication block X. The current command variable thus becomes sinusoidal. More precisely, the amount of the tracking mains voltage sin Θ is formed for the reference variable, since the input voltage of the PFC UB2 was also the amount of the mains voltage formed by the rectification. The control deviation ei is formed again from the difference of the target variable with the actual variable k. The actual size L is e.g. determined via a measurement of the coil current. A downstream regulator, e.g. Pl-member (Proportional Integrator), forms the control variable a from the control deviation ei. A PWM module can generate from the duty cycle a direct switching signal for the switch S of the PFC.

The data sequence s _n (t) is supplied in the extended control loop to a modulator which generates the modulation signal according to any modulation method. The modulation signal is impressed on the current setpoint (addition element) and fed to the current control loop. The carrier frequency fs of the modulation can be synchronized with the mains voltage by means of the reconstructed phase angle φ. Synchronization at this point is optional, but helps to provide more complex modulation techniques such as QAM modulation and OFDM directly with a phase reference formed by the line frequency. In particular, the demodulator on the receiver side thus receives a well to be reconstructed reference signal. The network frequency † N as a reference source is specified by the European Transmission System Operator Association (ENTSO-E) via the EN50160 standard to an accuracy of +/- 0.2 ~ Hz in normal operation, thus providing a very accurate reference signal. The product is formed from the reconstructed phase Θ and the desired size fs, normalized to fN. A modulo operation with 2pi generates the phase reference signal for the modulator. The existing technical structure of the PFC control loop does not need to be adapted further. The imprint of the message takes place via the current control loop. The use of a phase locked loop (PLL) to synchronize the load current with the line voltage is just one of many possible solutions used in PFC and power electronic circuits. The coupling into the current regulation can also be done in other topologies. Also a coupling via the voltage control or in the direct control of the valves is possible.

The output current of the PFC is determined by the control loop. The current loop is supplied with the reconstructed AC mains voltage via a multiplication block. In order to take into account the rectification of the input voltage, the amount of the mains voltage is supplied. Depending on the position of the current signal addition, the signal is modulated by f _N on the AC or DC side. If the addition of the message takes place before the magnitude is formed, then the signal without modulation is visible on the AC side, the modulated spectra can be seen on the DC side. This case is shown schematically in FIG.

The current message can also be integrated into the PFC control loop by coupling the signal into the feedback branch. In this case, PFC control loops implemented in integrated circuits (ICs) can be used. The signal addition takes place in this variant, however, after the amount formation. As a result, the modulation appears exactly on the other side of the rectifier bridge, as shown in FIG. To compensate for this, two carrier frequencies f _S i and fs 2 can be selected, which have a distance of 2 f _N to the desired signal frequency f _s (shown in Fig. 6).

The measured value acquisition for controlling the input current takes place by measuring the input current. The current measurement is carried out either via a shunt or via an inductive measured value acquisition. The analog value is fed to the current control loop analog or digitalized. The difference between the setpoint and the actual value gives the control deviation, which affects the input current. A current-modulated signal can now take place via an inductive or capacitive coupling into the measuring circuit and thus has the same influence as an addition of the current message in the reference signal. It is thus possible that an existing PFC circuit is supplemented by the current modulator in terms of hardware. The PFC design changes only slightly with this coupling method. Likewise, conclusions can be drawn on the input current by measuring the output current in combination with the input voltage, so that a power electronic circuit having a corresponding control variable detection, as well as a message signal can be impressed. It should be noted that the exact structure of the PFC circuit is not critical to the implementation of the invention. Optimal integration is possible via an intervention in the existing current regulation.

Additional circuit technology, which would cause increasing volume and higher cost of the equipment, is therefore not necessary.

The mentioned Power Factor Correction (PFC) is usually already part of any power electronic circuit with powers> 75W and is e.g. in PCs, chargers e.g. used by electric vehicles, consumer electronics, etc. Analogously, however, this technique is also used in bidirectional inverters, such as PV inverters or battery storage systems, low-power power supplies with PFC function such as single-stage flyback circuits or circuit topologies with upstream step-up or step down converter. Again, the invention may find application in the same way.

In one embodiment of the invention, the frequency of the modulated current signal is at least twice the frequency of the current to / from the power conversion device.

Thus, small amounts of data can be transmitted in a simple and secure way. For example, requires an (initialization) message only the information to set up the bidirectional communication. Thus, only a few 100 bytes are sufficient, a high data rate is not required for this. That with a frequency which is 200 Hz or higher, the information (without further precautionary measures) can already be sent.

In a further embodiment of the invention, the at least one power conversion device itself is a control device, which control device in turn is part of a further communication system according to one of the preceding claims.

That is, with the presented invention, it is possible to provide a cascading, so that control devices, for example, information from certain (subsequent) consumers can collect and provide a prepended control device available. Multiple controllers along the current path CT Transmitter Station can receive coupling information and couple with current transformers. The tree topology of the power grid is used. At the top is the local network station, from which the lines branch off via the house connection points to the consumers. Control devices can be placed in nodes such as individual line outlets and meter points such as smart meters. Control units can couple with all lower-level current transformers. As a result, several control levels are possible, for example · bottleneck management at the network connection point level and at the line leaving level

 • Local congestion management (voltage maintenance, overload ...), which requires knowledge of the location and identification of the controllable units.

In one embodiment of the invention, the communication system further comprises at least one further power conversion device, wherein the communication system provides communication between the control device and the first and the further power conversion device in the form of a point-to-multipoint communication. This is a typical situation in an arrangement where communication takes place from one power source to a plurality of loads.

In a further embodiment of the invention, the communication system further comprises at least one further power conversion device, wherein the communication system provides communication between the first power conversion device and the further power conversion device in the form of a point-to-point communication. This is a typical situation in an arrangement where the communication from a plurality of consumers takes place via the controller. Since the consumers involved are usually not in direct connection (in the sense of the tree topology) due to the damping characteristics, direct communication is only possible via a common control device.

In a further embodiment of the invention, the communication comprises at least one of data relating to bottleneck management, energy management, billing, resource properties, communication channel, encryption, etc. That is to say, with the invention, networking of many individual subscribers similar to the Internet of Things is made available on the power network by exploiting the properties of the power network, which allows state information to be collected and control tasks to be taken over by management systems.

In general, a coupling of the device to be controlled with a controller is necessary so that information is exchanged only between the terminal and the controller and terminals in outbuildings are not mistakenly part of their own control.

The coupling of devices is often a tedious process that requires the entry of IDs and keys.

The tree structure of the power grid can help to automatically couple these devices with controllers and at the same time to ensure the connection security through the automated transmission of a public key.

To secure the system, the communication can also be encrypted.

Tasks of the control devices can be:

 • bottleneck management to avoid resource overloads

 Energy management systems: aggregate mobile and stationary resource properties, such as State of charge (SoC), max. Charging power, desired timetable for charging an electric vehicle (EV) or stationary storage in a building. Negotiation of a roadmap between load and management system.

 • Coupling of consumers in multi-agent systems

 • Billing systems: Allocation of mobile loads to smart meter systems.

 Recording the consumption of the mobile device within the device. Transmission of consumption data to smart meters. Exchange of certificates between smart meter and consumer. Construction of a separate billing module.

 • Automatic forwarding of equipment properties and configuration such as PV systems in a low voltage network: e.g. Transmission of peak power, specification of P (f) and Q (U) characteristics. Controller can be placed in local network station and forward the optimal configuration to resources. Even mobile consumers like EVs can be configured

 • Automatic binding of household loads with smart home controllers. For example,

 Capture of bulbs in rooms. Lamp logs in the first connection to controller of a room and a house. Control of features such as on and off, brightness and color

 • Synchronized self-consumption: Coupling of a Sync Meter with Smart Meter in your own household I Connection points. Here, a unit which can measure and control itself is uniquely assigned by the invention to the controller to which it is connected.

 • Construction of a cascaded controller system. Several controllers along the power path consumer - local network station can receive coupling information and be paired with consumers. The tree topology of the energy network is used. At the top is the local network station, from which the lines branch off via the house connection points to the consumers. Controllers can be placed in nodes such as individual line outlets and meter points such as smart meters. Controller can only pair with all subordinate consumers. This allows multiple controller levels: e.g.

• Bottleneck management at the network connection point level and at the cable exit level Local congestion management (voltage maintenance, overload ...) requires knowledge of the location and identification of the controllable units

Claims

claims

1 . Communication system in a power supply network, comprising at least one control device and at least one power conversion device, wherein the power supply network at the same time the communication between the at least one power conversion device and the controller is used, is modulated for communication between the at least one power conversion device and the control device, the modulated current signal is superimposed on a current to / from the power conversion device, wherein the modulation is realized by a device selected from the group comprising Power Factor Correction, inverter.

 2. The communication system of claim 1, wherein the frequency of the modulated current signal is at least twice as large as the frequency of the current to / from the power conversion device.

 3. Communication system according to one of the preceding claims, wherein the at least one power conversion device itself is a control device, which control device is in turn part of a further communication system according to one of the preceding claims.

 4. The communication system of claim 1, further comprising at least one further power conversion device, wherein the communication system provides communication between the control device and the first and the further power conversion device in the form of a point-to-multipoint communication.

 5. The communication system of claim 1, further comprising at least one further power conversion device, wherein the communication system provides communication between the first power conversion device and the another power conversion device in the form of a point-to-point communication.

6. Communication system according to one of the preceding claims, wherein the communication comprises at least one of data related to congestion management, energy management, billing, resource properties, communication channel, encryption, etc. Communication system according to one of the preceding claims, wherein no modulated voltage signal is used for communication between the at least one power conversion device and the control unit.

Communication system according to one of the preceding claims, wherein a control message is generated by a power electronic circuit and is available as a modulated current signal.