NL2016736B1 - System for distributing power and method. - Google Patents

Abstract

System for distributing electrical current, comprising a first and a second current distribution device, each comprising an input for supplying current to the current distribution device to be supplied by a current source to be connected thereto, a current distributor for dividing the current to be supplied into current parts , and a number of outputs for outputting the current parts from the power distribution device to a respective number of current collection units, the first and second power distribution devices being adapted to supply current through a first and a second power source to be connected thereto and distributing a second group of current collection units, the system being arranged to output current to be supplied by the first current source to at least one current collection unit of the second group and / or to export current to be supplied by the second current source to at least one current collection unit of the e first group.

Description

System for distributing power and method

The present invention relates to a system and method for distributing power. More specifically, the present invention relates to an electrical power distribution system, comprising a first and a second power distribution device, each comprising an input for supplying to the power distribution device power to be supplied by a power source to be connected thereto, current distributor for dividing the current to be supplied into current parts, and a number of outputs for exporting the current parts from the current distribution device to a respective number of current collection units, the first current distribution device being arranged to be supplied by a first current source to be connected thereto to distribute current over a first group of current collection units and the second current distribution device is arranged to distribute current to a second group of current collection units to be supplied by a second current source to be connected thereto. The invention further relates to a method for distributing current, wherein current supplied by a current source is divided into current parts, each current part of which is supplied to a current-taking unit.

Apartment complexes usually have an extremely suitable roof for solar panels. However, a joint investment in solar panels has so far been unprofitable or impossible to implement due to current legislation, including tax legislation. In order to achieve a financially favorable settlement, the self-generated solar power must be fed directly into the energy system of an apartment and not into a collective meter. A solution is to split large installations of solar panels on the roofs of apartment complexes into several small installations with their own inverters. However, this is impractical, inefficient, costly and in most cases legally unfeasible.

A known solution is a power distribution device that ensures a distribution of the electricity generated by solar panels from an inverter over the individual meters of the participating apartments. As a result, the required split has been realized in a simpler manner in terms of hardware and the generated electricity is not only fed into a collective facility.

These known power distribution devices supply power to a fixed predetermined group of power collection units (in the example above these are the participating apartments) from an inverter. However, situations may arise in which a group of current collection units require more or less energy than can be supplied by the current distribution device. At such a moment, the power distribution device has an undercapacity or an overcapacity, respectively.

It is therefore an object of the invention to make better use of the capacity of power distribution devices.

To this end, the invention provides a system of the type mentioned in the preamble, with the special feature that the system is adapted to export current to be supplied by the first current source to at least one current collection unit of the second group and / or by the second current source to be supplied to at least one current collection unit of the first group. Such a system provides that one or more current collection units, such as apartments in an apartment complex, can be supplied with power from other or multiple power sources. In this way, undercapacity of a power source can be compensated by an overcapacity of one or more other power sources. This means that energy generated by multiple power sources can be better distributed in the long term.

According to a preferred embodiment, the system comprises a switching device for connecting one of the first and second power distribution units to the at least one power supply unit on the basis of a power supply part determined by a predetermined distribution key to the at least one power supply unit. As a result, a current collection unit, which in principle belongs to a first or second current distribution device, can be adopted by the second or first current distribution device. Such a system has the special advantage that the desired amount of current can be supplied to all current collection units of a certain group of current collection units, even though the current source that is in principle assigned to these current collection units cannot provide this. The current, whether or not generated by solar panels, is thus optimally distributed, also in situations where at a certain moment a current collection unit or a group of current collection units requires more current than can be supplied by the current source allocated to it, while at the same time another group of power take-off units requires less power than can be supplied by the power source assigned in principle to it.

According to a preferred embodiment, the system comprises a ballast for connecting current parts determined by the predetermined distribution key to the power collection units of the first and the second group from the first power source to the second power distribution device and / or the second power source with the first power distribution device, such that the first power distribution device can distribute power to be supplied by the second power source among the first group of power collection units and / or the second power distribution device can distribute power to the second group of power collection units. In this way connection of different power sources to a group of power take-off units is possible. This allows the power collection units to be supplied with power from another power source. A special advantage of such a ballast is that a whole group of current collection units can be supplied by another current source. Preferably, the other power source can also supply power to its own group of power collection units.

According to a preferred embodiment the system comprises a control and control unit connected to the power distributors of the first and the second power distribution device for controlling the power distributors in order to control the distribution in the power parts to be executed on the basis of the distribution key and in dependence on a amount of current to be supplied to the first and second power source. A particular advantage of such a control and control unit is that the current supplied by the power sources is distributed in proportion to the expected consumption of each individual power take-off unit. In this way, feed-in of electricity to the meter (s) (read: to the electricity network) is minimized.

According to a preferred embodiment, the switching device and / or the ballast device is connected to an input-output terminal of the control and control unit. In this way, the control and control unit can control the switching device and / or the switching device in order to optimally use the available amount of current to be supplied over the current-taking units on the basis of the distribution key and in dependence on an amount of current to be supplied by the first and second current source. to divide. This provides for further optimization of the use of the available amount of power.

According to a preferred embodiment, the system comprises a solid-state switch arranged between the first current source and the first current distribution device and / or the second current source and the second current distribution device for switching off the first and / or second current source. A special advantage of such a solid-state switch is that the voltage of one or more current sources can be switched off without using one or more magnetic switches of a current distributor. This allows switching under full load without causing arcs and / or damage to the magnetic switches and / or other components.

According to a preferred embodiment, the control and control unit is adapted to automatically adjust the distribution key to a current power demand of the first and second group of power take-off units and a current quantity of power to be supplied by the first and second power source. A particular advantage of such a real-time coordination between the supply, ie the deliverable amount of power, and the demand, ie the desired power draw from the power draw units, is that feed back to the meter (s), ie to the electricity grid , is minimized as much as possible. This is particularly advantageous in situations where the current supply from a current source and / or the current demand from a current collection unit is highly variable.

According to a preferred embodiment, the control and control unit is adapted to communicate with a server. Such a server makes it possible to consult data stored on the server at any time. Data may be stored on the server with regard to the configuration of the power distribution devices or of the system, as well as updates that are necessary for the proper functioning of the system. Similarly, the system can send log data to the server, such as error messages, as well as data regarding power yield and power draw.

According to a preferred embodiment, the control and control unit comprises a transmitter-receiver unit for wirelessly sending and receiving signals. In this way it is possible to control the system remotely. This allows the power collection units (for example, residents of an apartment complex) to easily pass on their power demand to the system. This makes the system particularly user-friendly.

According to a preferred embodiment, the system further comprises an energy meter which is connected to an input-output terminal of the control and control unit. A special advantage of such an energy meter is that it can measure the amount of energy supplied by the power source. This measured value can then be entered in the control and control unit for flow distribution optimization.

According to a preferred embodiment, the system is arranged to connect at least one of the first and the second current source thereto via an inverter. The inverter is, for example, a direct-current alternating current converter. Such an inverter enables the current from current sources that produce a direct current to be converted into alternating current in order to make it suitable for a variety of domestic and non-domestic applications.

According to a preferred embodiment, the system further comprises energy storage means. A particular advantage of such energy storage means is that the power that is not directly used by power take-off units is stored and not returned to the meter (s) as a surplus. At a later time, the energy stored in such energy storage means can be used when the power requirement is greater than the deliverable amount of power. On this, as little electricity as possible flows back to the meter, which contributes to maximizing the profitability of the system. Such energy storage means are preferably connected to the inverter on a direct current side or an alternating current side thereof. Optionally, the energy storage means are connected as a power collection unit to the power distribution device on an output side thereof.

According to a preferred embodiment, at least one of the first and the second power source comprises a renewable power source. Such a source extracts energy from elements of the earth and is almost inexhaustible. Examples of such a source are solar panels, wind turbines, hydroelectric power stations and geothermal power stations.

According to a preferred embodiment, the renewable power source comprises a panel of photovoltaic cells. The system according to the present invention is particularly suitable for use in combination with panels of photovoltaic cells, i.e. solar panels, since such panels are expensive and profitability is therefore an important aspect in the consideration of purchasing solar panels. The system maximizes the use of renewable energy generated by solar panels and thus minimizes the return on investment.

The invention further relates to a method of the type mentioned in the preamble, with the special feature that the current is supplied from at least a first and a second current source, which are arranged electrically parallel to each other, and on the basis of a predetermined determined distribution key and in dependence on a quantity of current to be supplied by the first and second current source. Such a method provides that one or more current collection units, such as apartments in an apartment complex, can be supplied with power from other or multiple power sources. In this way, undercapacity of a power source can be compensated by an overcapacity of one or more other power sources. This means that energy generated by multiple power sources can be better distributed in the long term. Preferably, the desired amount of current can be supplied to all current collection units of a particular group of current collection units, even though the current source which is in principle assigned to these current collection units cannot provide this. The current, whether or not generated by solar panels, is thus optimally distributed, also in situations where at a certain moment a current collection unit or a group of current collection units requires more current than can be supplied by the current source allocated to it, while at the same time another group of power take-off units requires less power than can be supplied by the power source assigned in principle to it. Preferably, the method allows connection of different power sources to a group of power take-off units. This allows the power collection units to be supplied with power from another power source. A special advantage of such a switching device is that a whole group of current collection units can be supplied by another current source. Preferably, the other power source can also supply power to its own group of power collection units.

According to a preferred embodiment, one of the plurality of power sources comprises a panel of photovoltaic cells. The method according to the present invention is particularly suitable for use in combination with panels of photovoltaic cells, i.e. solar panels, since such panels are expensive and profitability is therefore an important aspect in the consideration of purchasing solar panels. The method maximizes the use of sustainable electricity generated by solar panels and thus minimizes the payback period of the investment.

According to a preferred embodiment, use is made of a system for distributing electrical current, preferably a system according to a preferred embodiment of the present invention.

Typically, the system comprises a server software installed on the server, whether or not wirelessly connected to the control and control unit (not shown in the figures), for communication with client software installed on the control and control unit and a web interface. The primary components of the server software consist of a client application program interface ("client API"), a database and a graphical user interface ("GUI"), which presents data to users (such as residents of an apartment complex) ) and offers them various functionalities.

Preferred embodiments of the system and method according to the invention further comprise one or more of the following features, which may be used both individually and in combination with one or more other of the following features:

The energy meter (s) are provided in the form of Wh-pulse counter (s) (or kWh-pulse counters / S0-pulse counters).

The server software transmits a target value for each channel. The target values for all channels are summed, and the client software calculates a target fraction ("target fraction") for each channel based on the target values and the total deliverable amount of power.

The server software provides a maximum value (for example in kWh) for each channel. This value specifies the maximum power that a channel can receive.

The server software transmits a "day mask" for each channel. This value specifies on which days a channel can be supplied with electricity (for example if a user has a lower electricity tariff during the weekend).

On the graphical user interface, an administrator specifies the maximum value per channel, for example in kWh, and selects the days on which delivery can take place. A manager also directly or indirectly determines the target values (as percentages of the total amount of electricity that is expected in a year).

The client software keeps track of how much power is supplied per connected power source and per channel. Based on this, the client software calculates a fraction of the current supplied per channel.

The server software contains internal counters, which can be changed remotely, for example for keeping track of the energy supplied within a distribution.

Connected to the input-output connection points of the control and control unit are: a Wh-pulse counter and the channels consisting of magnetic switches, each consisting of a magnetic relay and a switch contact.

The magnetic switches are placed inside the system (central circuit) or outside the system (decentral circuit, or an external box near the connection object) Connection objects are: a group / automatic in a meter cupboard of a home, or a collective facility connection (“CVZ ").

The server software specifies the relative priority of one channel over other channels.

The server software uses information about the topology and capacity of the various connections in the system: o For each channel group, the server software specifies the type and maximum power of the power sources that are connected. o For each channel, the server software specifies a unique identifier for the associated connection. o The server software specifies the maximum power that can be supplied per channel (total and per phase, as well as the maximum permitted power difference between the phases). o For each channel, the server software specifies the phase to which it is connected (L1, L2, L3) if this information is available and relevant.

The server software uses information about the connection and control of the control and control unit and the components connected via the input-output connection points: o For each channel group, the server software specifies which channels are connected to which input-output connection points of the control and control unit . o For each channel group, the server software specifies whether a ballast is present, and if so, at which input / output connection point of the control and control unit. o For each channel group, the server software specifies which Wh-pulse counter is used (on which input from the control and control unit).

The server software specifies how configurations of output signals on the control and control unit translate into possible combinations of power sources and channel groups. The server software specifies the connection and meaning of any additional switches, input signals and Wh-pulse counters.

The client software keeps statistics per power source, which determines the actual relative power of the power sources.

Systems on the same network exchange information with each other, in particular on the use of and the supply of power on any shared channels.

The server software indicates one or more times during the day to switch to another channel based on the current or upcoming power consumption of the connection objects (for example, the power consumption of a home).

More than one power source is connected per system.

Separate channel groups are defined to prevent a power source from simultaneously supplying more than one active channel, thereby connecting connections behind the meter to each other. This prevents unsafe situations, such as a large current between homes or connection of different phases with each other, as a result of which high voltages can occur.

One or more power sources are connected to a channel group, but a power source may only make contact with a channel group at any one time.

Based on the hardware of the control and control unit, several channel groups are defined per system, each with its own energy meter, such as a Wh-pulse counter.

The hardware and software make it possible to connect multiple power sources to multiple channel groups ("multiplexing" of power sources).

A solid-state switch is placed between the current sources and a channel group, with which the voltage of the current sources can be switched off without using the magnetic switches. This is used to switch under full load (for example during the day), preventing arcs and damage to the magnetic switches.

The client software ensures that only one channel is switched on within a channel group.

The client software makes it possible to connect two channels (from two different channel groups, each with a separate power source) to a connection object.

The client software continuously checks the status of all switch contacts, and switches off all relays in a channel group if more than one channel is active in the group (ie more than one channel is open), or if a power source is linked to more then a channel group (for example due to a defective relay).

If there are shared connections in an installation, the client software checks the status of the relays of other channel groups and / or power distribution devices connected to the shared connection.

There is a secure communication connection between the server software and the client software, so that both client and server can take the initiative for communication.

There is a secure communication connection between the power distribution devices, so that data exchange is possible between all power distribution devices in a system and / or an assembly of systems, even in the absence of a connection to the server software.

Security of the communication connection is based on a public / private-key infrastructure and point-to-point encryption (i.e. encryption).

Communication between client and server software is based on a data model, with which structured information can easily be exchanged.

The server and client software keep information about the physical topology of the installation, and about the properties of power sources and connections.

The server and / or client software includes adaptable distribution algorithms for switching flexibility and processing of additional information and preconditions.

Power distribution is based on an entire installation, i.e. an assembly of systems in which multiple power sources and solar power distributors can be present. This makes an optimum distribution of power possible, especially if there are shared connections in an installation.

The server and / or client software makes it possible to read out and / or control, via the input / output connection points of the control and control unit, several Wh-pulse counters, but also external hardware (for example a battery or inverter). This allows storage technology, such as a battery, to be added as a connection object.

In principle, the system only switches to another channel if the power source does not supply any power. This is before sunrise and after sunset, or in the presence of a solid-state switching relay. Reasons for switching earlier may be: o Restarting hardware or software. o Remote control of the system (for example via SMS). o Detection of problems (with switches or power supply), o Achieving the maximum value (the maximum amount of power to be supplied) on a channel.

Manual or automatic control of switches from the server software is possible at any time via an optionally present secure communication connection.

At a switching moment, the system can independently select multiple channels and control additional switches if necessary. Optionally, the system chooses which power source supplies the power based on predefined configurations per channel group.

A maximum of one channel may be active at any one time. At the time of switching, the current client software determines the channel on which delivery will be made, based on: o Possible problems that the client software has detected (non-functioning switches, problems with the supply of energy, etc.). In case of problems, a channel is switched off, skipped or only briefly switched on for testing, depending on the situation. o The exceeding of a possible maximum value (maximum amount of energy to be supplied). If the maximum is exceeded, a channel is switched off or not switched on. o The day of the week and the "day mask". If the day does not match the day mask of a channel, the channel will not be switched on, o The deviation between the target fraction (the fraction of the total energy to be supplied) and the fraction of the energy actually delivered. If other above-mentioned preconditions are met, then the channel with the largest deviation is switched.

In addition to the aforementioned preconditions (target fraction deviation, maximum value, day mask deviation and hardware status), the client software uses the following preconditions to determine which channel becomes active: o The relative priority of a channel.

If both a priority and a maximum value are defined for one or more channels, the channel with the highest priority receives all current (within the other preconditions with the exception of deviation), until the maximum is reached.

If no maximum is given and several channels are eligible to be switched on, the channel with the highest priority is selected. o The physical topology and capacity of the connections in the system and the power sources:

If more than one channel supplies power to the same connection (i.e., there are multiple channels that have the same identification in the client software, usually in different channel groups). In such cases: • the client software ensures that the number of power sources to be switched on at the same connection remains limited based on the maximum power of the power sources and the maximum capacity of the connection; and • the client software ensures, if possible and relevant, that the power supplied is properly distributed over the connected phases.

If more than one power source can be selected within a channel group or channel: • the client software selects one or more power sources, so that the maximum power to be delivered from a channel is not exceeded, • the client software chooses the power sources per channel or channel group, such that the expected deviation from the target values is minimized.

If one or more of the connected power sources is a battery, the client software takes the remaining capacity of the battery into account when switching on or off power sources. In addition to an optimal power distribution based on the target values per channel and connection object, the client software also ensures real-time coordination between the supply of the power source (s) and the demand of the power supply units / connection objects. In this way, feed-in of electricity / energy to the electricity grid is minimized.

Further advantages, features and details of the present invention will be elucidated on the basis of the following description of a preferred embodiment thereof, with reference to the accompanying drawings, in which: figure 1 shows a perspective view of a cross-section of a building, in which a system according to a preferred embodiment of the invention is connected to solar panels; 2-4 show diagrammatic overviews of systems according to preferred embodiments of the invention; and figure 5 shows a schematic overview of a system according to a preferred embodiment of the invention.

Figure 1 shows a perspective view of a building 100, for example an apartment complex, on which power sources 201, 202, 203, 204, such as solar panels, are arranged. Outputs from solar panels 201-120 are connected to a power distribution system 500, consisting of various power distribution devices 601, 602, in order to distribute the power generated by solar panels 201-204 to apartments and / or collective spaces 101, 102, 103, 104. The current generated by solar panels 201-204 is fed via inputs 1711, 1721 to power distribution devices 601, 602 of power distribution system 500. Between inputs 1711, 1721 and solar panels 201-204, direct current alternating current converters 301, 302 are placed around the direct current from solar panels 201- 204 to AC power that can be used by households. Furthermore, power distribution system 500, on the basis of a power distribution key determined by the power demand of the apartments / collective areas 101-104 and the power supply of the solar panels 201-204, divides the power generated by solar panels 201-204 and feeds it through outputs 1811, 1821 into electricity meters 1001, 1002, 1003, 1004 of the individual apartments / collective space (s) 101-104. Between power distribution system 500 and each electricity meter 1001-1004, a switch box 2001-2004 is optionally included to direct the alternating current distributed by power distribution devices 601, 602 of power distribution system 500 to electricity meters 1001-1004 of other apartments / collective space (s) 101-104.

Figure 2 shows a schematic overview of a system 500 of power distribution devices 601, 602, 603 according to the prior art, wherein power from three different power sources 201, 202, 203, such as solar panels, is distributed among five different power take-off units 1001-1005 , such as apartments in an apartment complex or households in a residential area. Here, current generated by current source 201 is divided between current collection units 1001 and 1002, current generated by current source 202 is distributed across current collection unit 1003 and current generated by current source 203 is divided between current collection units 1004 and 1005. Between current sources 201-203 and inputs 1711 1721, 1731 of the current distribution devices 601-603 of the current distribution system 500, converters 301, 302, 303 are provided, for example for converting direct current generated by current sources 201-203 into alternating current usable by households. Furthermore, the power distribution devices 601-603 include energy meters 801, 802, 803, which can measure the amount of energy supplied by the power sources 201-203. The measured values can then be used for system distribution optimization by the system 500. Separate channels 911, 912, 921, 931, 932 can be distinguished from one another in the power distribution devices 601-603. Channels 911, 912, 921,931, 932 are then connected to outputs 1811, 1812, 1821, 1831, 1832 of the power distribution devices 601-603, which feed in the distributed current to the electricity meters / connection objects 1001, 1002, 1003, 1004, 1005 of the power collection units / apartments 101, 102, 103.

Figure 3 shows a schematic overview of a preferred embodiment of the invention, wherein power distribution device 602 and power distribution device 603 are both connected to one and the same connection object 1004. The power distribution system 500 is adapted to output power to be supplied from power source 202 to terminal object 1004 and / or to output power to be supplied from power source 203 to terminal object 1004. For this purpose, the system comprises a switching device for connecting one of power distribution devices to terminal object 1004. 602 and 603 on the basis of a current part determined by connection object 1004 by a predetermined distribution key. As a result, connection object 1004, which in principle belongs to power distribution device 602, can be adopted by power distribution device 603 as it were. Such a system has the special advantage that the desired amount of current can be supplied to all current collection units of a certain group of current collection units, even though the current source that is in principle assigned to these current collection units cannot provide this. Thus, the power generated by solar panels or not is optimally utilized, also in situations where at a certain moment a power take-off unit or a group of power take-off units requires more power than can be supplied by the power source assigned to it in principle, while at the same time another group of power take-off units requires less power than can be supplied by the power source assigned in principle to it. In this way, undercapacity of a power source can be compensated by an overcapacity of one or more other power sources. As a result, the available power is used directly as much as possible and is not supplied back to the meter, which increases the profitability of, for example, solar panels.

Fig. 4 shows a schematic overview of a preferred embodiment of the invention, wherein power distribution system 500 includes ballasts 701, 702 for connecting power source 202 to power distribution device based on current parts determined to power take-off units 1003-1005 603 and / or power source 203 with power distribution device 602, such that power distribution device 603 in addition to power to be supplied by power source 203 can distribute at least a portion of power to be supplied by power source 202 among power take-off units 1004, 1005 and / or power distribution device 602 in addition to can supply current to be supplied by current source 202 at least a portion of current to be supplied by current source 203 to current collection unit 1003. In this way connection of several current sources to one or more groups of current collection units is possible. This allows a group of power take-off units to be supplied with power from a different power source. A particular advantage of such ballasts is that a whole group of current collection units can be supplied by another current source. Optionally, system 500 has a solid state switch 400 provided between power source 203 and power distribution device 603 for switching off the power source 203. A particular advantage of a solid state switch 400 is that the voltage from power source 203 can be switched off without a or use multiple magnetic switches of power distribution device 603. This allows switching under full load without causing arcs and / or damage to the magnetic switches and / or other components.

Figure 5 shows a schematic overview of a system 500 according to a preferred embodiment of the invention, in which the relevant components of system 500 are shown. Figure 5 again shows three power sources 201-203 which are connected via inverters 301-303 to inputs 1711, 1721, 1731 of system 500. For example, power sources 201-203 can be solar panels 201-203 placed on a roof of an apartment complex 100 or other building, whereby solar panels 201-203 can be arranged to supply 1-phase current or 3-phase current to system 500. Inverters 301-303 can typically be direct-current alternating current converters for converting direct current generated by solar panels 201-203 into household-usable alternating current. System 500 comprises four channel groups 910, 920, 930, each consisting of a plurality of channels, which include switches 911-913, 921-923, 931-933, respectively. Group 940 comprises two magnetic switches, which can be operated independently of each other and of the other groups, for switching external equipment. Each of the switches 911-913, 921-923, 931-933 is connected via one of the outputs 1811-1813, 1821-1823, 1831-1833 to an electrical measuring device of a current collection unit (also referred to as a connection object), typically via a switch. System 500 further comprises energy meters 801-803, each measuring the amount of energy supplied by one or more power sources 201-203 connected thereto. Optionally, system 500 can also operate without energy meters 801-803, the amount of energy generated by current sources 201-203 being read out from the inverters 301-303. An important part of system 500 is control and control unit 1100 for controlling the power distribution devices 601-603 to control the desired power distribution. Input-output connection points 1510 of control and control unit 1100 are therefore connected to inputs 1901-1903 of energy meters 801-803, whereby control and control unit 1100 can measure the amount of current supplied by the current sources 201-203. Furthermore, input-output terminals 1520 of control and control unit 1100 are connected to switches 911-913, 921-923, 931-933 to control the distribution in the current parts to be output based on a predetermined distribution key and in dependence on a amount of electricity available from the 201-203 power sources. Control and control unit 1100 is powered by power supply 1600 and in turn feeds energy meters 801-803 through connection points 1530. Control and control unit 1100 is typically an assembly of programmable components with which the various input / output connection points 1510, 1520 can be controlled and / or and which control communication with a server not shown in the figures. In a typical design, the control and control unit 1100 comprises a custom-made printed circuit board ("PCB"), the most important of which are a so-called System On a Chip 1300 ("SOC"), a microcontroller 1200 and a GPRS module / GSM modem 1400. for wireless remote control / communication. More specifically, control and control unit 1100 may include a switch module, an embedded ARM module, and a separate GPRS modem. Control and control unit 1100 can therefore be set up in a multiform manner.

The invention is not limited to the embodiment shown, but also extends to other preferred variants that fall within the scope of the appended claims.

Claims (17)

A system for distributing electrical current, comprising a first and a second current distribution device, each comprising: an input for supplying to the current distribution device current to be supplied by a current source to be connected thereto; a current distributor for dividing the current to be supplied into current parts; and a number of outputs for outputting the current parts from the current distribution device to a respective number of current collection units, the first current distribution device being adapted to distribute current to a first group of current collection units to be supplied by a first current source to be connected thereto second power distribution device is adapted to distribute power to a second first group of power take-off units to be supplied by a second power source to be connected thereto, characterized in that the system is arranged to output power to be supplied by the first power source to at least one current collection unit of the second group and / or output current to be supplied by the second current source to at least one current collection unit of the first group. A system according to claim 1, further comprising a switching device for connecting one of the first and second power distribution units to the at least one power supply unit on the basis of a predetermined distribution key assigned to the at least one power supply unit certain power part. 3. System as claimed in claim 1 or 2, further comprising a ballast for connecting current parts determined by the predetermined distribution key to the power collection units of the first and the second group from the first power source to the second power distribution device and / or the second power source with the first power distribution device such that the first power distribution device can distribute power to be supplied by the second power source among the first group of power take-off units and / or the second power distribution device can distribute power to be supplied by the first power source among the second group power collection units. 4. System as claimed in any of the claims 2 or 3, further comprising a control and control unit connected to the power distributors of the first and the second power distribution device for controlling the power distributors in order to control the distribution in the power parts to be executed on the basis of the distribution key and in dependence on a quantity of current to be supplied by the first and second current source. System as claimed in claim 2, 3 or 4, wherein the switching device and / or the switching device is connected to an input-output connection point of the control and control unit. A system according to any of claims 1-5, further comprising a solid-state switch arranged between the first current source and the first current distribution device and / or the second current source and the second current distribution device for switching off the first and / or second current source . A system according to any one of claims 1-6, wherein the control and control unit is adapted to automatically adjust the distribution key to a current power demand of the first and second group of power take-off units and a current current deliverable by the first and second power source amount of power to be supplied. A system according to any of claims 1-7, wherein the control and control unit is adapted to communicate with a server. The system of any one of claims 1-8, wherein the control and control unit comprises a transmitter-receiver unit for wirelessly transmitting and receiving signals. The system of any one of claims 1-9, further comprising an energy meter connected to an input-output terminal of the control and control unit. 11. System as claimed in any of the claims 1-10, which is adapted to connect at least one of the first and the second current source thereto via an inverter. 12. System as claimed in any of the claims 1-11, further comprising energy storage means. The system of any one of claims 1-12, wherein at least one of the first and the second power source comprises a renewable power source. The system of claim 13, wherein the renewable power source comprises a panel of photovoltaic cells. 15. A method for distributing current, wherein current supplied by a current source is divided into current parts, each current part of which is supplied to a current-taking unit, characterized in that the current through at least a first and a second current source, which is electrically are arranged in parallel to each other, are supplied and are distributed on the basis of a predetermined distribution key and in dependence on a quantity of current to be supplied by the first and second current source. The method of claim 15, wherein one of the plurality of power sources comprises a panel of photovoltaic cells. A method according to claim 16, wherein use is made of a system according to any of the claims 1-14.