PHOTOVOLTAIC SYSTEM

专利摘要:
The invention relates to a photovoltaic system (1) having at least one photovoltaic module (2), at least one inverter (3) and at least one control unit (4), wherein the photovoltaic system (1) for feeding at least a first electrical load (5) and a public electricity grid (6) is carried out, wherein for measuring the electrical power (6) supplied electrical power (7) a power meter (8) is provided and the control unit (4) for controlling the electrical load (5) recorded electrical power (9) executed and a control unit (4) and a method for controlling such a photovoltaic system (1).
公开号:AT510938A1
申请号:T145/2011
申请日:2011-02-03
公开日:2012-07-15
发明作者:Werner Atzenhofer
申请人:Logotherm Regelsysteme Gmbh；
IPC主号:

专利说明:

* · · · · · · · · · · · · * * Ft ft
50047 Ag / FI Logotherm Regelsysteme GmbH 5
Photovoltaic System The invention relates to a photovoltaic system with at least one photovoltaic module, at least one inverter and at least one control unit, wherein the photovoltaic system is designed to supply at least a first electrical load and a public electricity grid. 15 private photovoltaic systems are used for the direct conversion of solar energy into electrical energy by means of solar cells. For this purpose, special photovoltaic modules are provided which generate DC voltage and are usually provided with an inverter to obtain the required AC voltage in the household. 20 Such photovoltaic systems are currently used in private households primarily to drive electric heat pumps. Such heat pumps are generally used for heating purposes, for heating of process water, or even in summer for cooling purposes. The regulation of such a photovoltaic system is typically carried out by a dedicated control unit, which distributes the electrical power generated by the photovoltaic system depending on preset parameters to the consumer or consumers.
However, due to the fact that the generation of the photovoltaic energy and its consumption often take place with a time delay, the entire photovoltaically generated energy can not be consumed locally directly after the production. Instead, the excessively generated electrical energy is usually fed into a public electricity grid, whereby a specific remuneration (feed-in tariff) can be obtained from the private household for this fed-in electric energy. As a guideline, it can be assumed that only about 30% - 40% of the 35 locally produced electrical energy is consumed locally. 14 «tf · 14« tf · ϊ: * »· ··»
50047 Ag / FI Logotherm Regelsysteme GmbH
However, both political and private endeavors are increasingly moving towards direct photovoltaic use in the home, and feeding into the public electricity grid only in exceptional cases, if at all. 5
In addition, it is becoming apparent that households are increasingly having more and more electrically-chargeable consumers, such as electrically-chargeable cars, electric bicycles, scooters, lawnmowers, portable computers, etc. It would be desirable to have the electrical power generated by an existing photovoltaic system in the space direct consumption in the household, and only if there are no other means of transferring electric power into the public electricity grid. However, existing photovoltaic systems in particular are set up for feeding into the public electricity grid as described above. The technical object of the present invention is therefore to propose an improvement of existing photovoltaic systems, whereby a self-use of the generated electrical energy can be achieved to a greater extent, without completely abandoning the feed into a public electricity grid. In particular, it should be possible to adapt existing photovoltaic systems to fulfill this task.
This object is achieved in that a power meter is provided and the control unit is designed to control the electrical power absorbed by the first electrical load. 25
The first electrical load may preferably be an electric heat pump for heating, cooling, or for generating hot water.
In contrast to the state of the art, in which the electrical load, in which the electric heat pump is usually operated at fixed power, and the excess power is fed into the electricity grid, the control unit according to the invention can adjust the power of the first electrical load in that as little as possible, no or a specific target value of electrical power is fed into the electricity grid. In particular, this target value may be dependent on external factors, for example the time of day. * T »: 3
50047 Ag / FI Logotherm Regelsysteme GmbH
According to the invention, the control unit can preferably be in operative connection with the power meter and the electrical load, so that the consumed electrical power of the load is matched directly by the control unit.
The power meter may preferably be designed both for measuring the electrical power supplied to the electricity grid and for measuring the electrical power related to the electricity grid. In particular, a first connection of the power meter to the control unit for transmitting the power delivered to or from the electricity network, and a second connection of the control unit to the first electrical load to control the power consumption of the first electric-15 cal consumer can be provided.
As mentioned above, the first electrical consumer may preferably be a heat pump, but also an electrical heating resistor, an e-electric charger or the like. This first electrical load 2o may be connected to a buffer storage, for example a hot water storage, to temporarily store the energy for later use.
The inverter may in particular be an inverter with an MPP tracker, which converts the DC voltage 25 supplied by the photovoltaic module into 230V or 400V AC voltage.
In addition to the first electrical load, in particular the heat pump, according to the invention provision is made for at least one second electrical load to be connected to the control unit in order to allow the control unit to utilize electrical excess power. This may preferably be an electric heater, an electrically rechargeable battery, or any e-lektrische charging stations for electrically powered vehicles, tools, electronic devices or the like. ψ * • · 4
50047 Ag / FI Logotherm Regelsysteme GmbH
According to the invention, it is further provided that electrical power is fed into the household power supply via an external battery or a battery pack and via an inverter. The power of the inverter, which is taken from the battery can be adjusted via an output of the controller, 5 that the power supplied to the network results in a target value, in particular the value zero. This may then be required, the power generated by the photovoltaic module is higher than the sum of household utility and power of the electrical consumers (heat pump, chargers, etc.), and yet no electrical power to be delivered to the public network (due to a too low -io gen feed-in tariffs).
The charge of the battery must not fall below a certain, battery-specific charge minimum value due to the otherwise reduced battery life. For this reason, it can be provided according to the invention that the inverter connected to the battery 15 is switched off when this minimum charge value is undershot.
Furthermore, it can be provided that the charge state of the battery is monitored with a battery monitor. This battery monitor can record the power drawn in and out of the battery and always monitor the battery's current state of charge. This state of charge can be communicated to the control unit via an interface.
Furthermore, the invention provides that the battery is charged by a cheaper 25 electricity tariff, for example night stream. The maximum charge can be limited by the control unit in order to be able to store a possible surplus of electrical photovoltaic power via the battery during the day and not have to feed it into the public grid. Furthermore, the otherwise required at night power can be compensated by the battery. 30
By using the battery so energy consumption fluctuations in the household can be compensated. Without a battery you would have to draw electricity from the public grid in this case. The battery thus acts as a power failure fuse or uninterruptible power supply (UPS) in the event that the public network fails. For this purpose, it may be provided that the
5
50047 Ag / FI Logotherm Regelsysteme GmbH different consumer groups in the household are assigned different priorities, for example, heating and cooling units have the highest priority, and are supplied in the event of a power failure of the battery. In order to be able to ensure a corresponding battery supply, it may be provided that the battery must have a minimum charge, and accordingly always be supplied with electrical photovoltaic power in the battery until the minimum charge is reached. Furthermore, it can be provided that the battery charging logic can have different operating modes. For example, in the case of high efficiency, the battery can be discharged at night to an absolute minimum to be recharged the next day. In contrast, in the case of high power failure safety, the battery can be recharged at a certain defined value, and possibly even recharged by the public network, to be able to survive in an emergency, if the public network fails, for example, at least two days without a public network.
According to the invention, the battery can be charged by excess photovoltaic power after a set priority and / or a time window. In this case, the other electrical consumers, in particular the heat pump can be considered.
The battery or battery pack may be any rechargeable power source based, for example, on electrochemical (accumulators) or electrostatic (capacitors) function.
The present invention further extends to a control unit for a photovoltaic system according to the invention. Such a control unit comprises in particular 30 a control input, a control output, a controller and at least one electrical switching stage for controlling electrical consumers.
It may further be provided according to the invention that the control unit comprises an electric power supply, an electronics unit and a user interface. 35 6
50047 Ag / Fl Logotherm Regelsysteme GmbH
Finally, the present invention comprises a method for controlling the electrical power delivered by a photovoltaic system to a first electrical consumer and to a public electricity network, wherein the electrical power transmitted to the electricity network is measured and the power consumption of the first electrical consumer is adjusted until the electrical power delivered into the electrical grid reaches a predetermined value, in particular the value zero.
According to the invention, it may be provided in this method that, if necessary, in addition to the first electrical load, at least one second electrical load is supplied with electrical power until the electrical power delivered into the electricity grid reaches a predetermined value, in particular the value zero. This also includes the measurement of negative transmitted power, in other words, the case where electrical power from the electricity grid is related. In this case, electrical loads are switched off, or the power consumption of the first electrical consumption is reduced until the target value for the power delivered to the electricity network, in particular the value zero, is reached. In this case, the connection or disconnection of the electrical consumers can be made according to a pre-determined priority list. In particular, it may further be provided according to the invention that the power consumption of the electrical consumers is maintained within a predetermined optimum range. The present invention is not limited to the fact that the first electrical consumer is a heat pump, but all moldings of first and second electrical consumers. By way of example, the first electrical load may be an electrical energy store (capacitor, battery), the second electrical load may be a motor vehicle charging station, and only the third electrical load may be a heat pump. The priority of the electrical consumers can be adapted to the application.
Further advantageous features are described in the description, the drawings and the claims. 35 Μ ··· * • · «« Ψ «· ·« · «···· · •« «η» »* * · · ·« «» V «· t · ·
7 50047 Ag / FI
I.ogotherm Regelsysteme GmbH
The invention will now be described in more detail by means of embodiments in the following figures. Show it
1 shows a schematic block diagram of a photovoltaic array according to the invention;
FIG. 2 shows a schematic block diagram of a control unit according to the invention for a photovoltaic system according to FIG. 1; FIG.
3 is a schematic flow diagram of a method according to the invention for controlling a photovoltaic system; FIG. 4 shows a schematic block diagram of a second embodiment of a photovoltaic system according to the invention; FIG.
5 shows a schematic block diagram of a control unit according to the invention for a photovoltaic system according to FIG. 4; FIG. Fig. 1 shows a schematic block diagram of a photovoltaic system 1 according to the invention with a photovoltaic module 2. The photovoltaic module 2 generates DC voltage and is connected to an inverter 3 with MPP tracker, which converts the DC voltage into an AC voltage with 230V and 50Hz. The inverter 3 supplies the electrical power θθ 16, which splits into a portion of the electrical power Pwp 9 delivered to a first electrical load 5, a useful power component PNutz 31 and an electrical power Pneu 7 supplied to an electricity network 6. A power meter 8 measures the power Pnetz transmitted to the public electricity network 6 and is connected to a control unit 4 via a first connection 10. The control unit 4 is connected to the electrical voltage supplied by the inverter 3 25 and further has a second connection 11 with the first electrical consumer. 5
The power meter 8 is designed such that both positive (power supplied to the power grid 6) and negative (power sourced from the power grid 6) power values can be measured.
The first connection 10 is designed such that information about the measured power can be transmitted from the power meter 8 to the control unit 4, and the second connection 11 is designed such that the control unit 4 adjusts the electrical power received by the first electrical load 5 , «* ·· * * * * *» · »· • · · * * * * * φ
β 50047 Ag / FI
Logotherm Regelsysteme GmbH
In addition, the first electrical load 5 with a buffer memory, such as a hot water tank, connected. By means of the first connection 10 and the second connection 11, the control unit 4 is able to control the power absorbed by the first electrical load 5, depending on the power PnBt2 7 supplied to the network.
Furthermore, the control unit 4 has outputs to a plurality of second electrical loads 25, in the present example, an electric heater insert 13 and an electrical charging station 14. This may preferably be a charging station io for electric vehicles, electronic equipment, tools or the like. Depending on the measured power P, * * 7, the control unit can switch on one or more electrical consumers, whereby an excess power Pu is additionally transmitted. The control unit can thus adjust the power Pnetz 7 transmitted to the public electricity network to a specific value, in particular the value zero, and make appropriate use of the excess power by switching on certain electrical consumers. For example, the surplus power generated in the event that just little power 31 is needed, the first electrical load 5 is running at full capacity and the feed-in tariff for the network power 7 supplied to the grid is unfavorably used entirely for electric chargers or comparable consumers.
In particular, it can be provided that when switching on the consumers, a priority list is used which can be time-dependent or time-controlled. Furthermore, the control unit 4 itself is also supplied by the electrical power Pei 16 generated by the photovoltaic module 2, whereby this energy consumption is low and was not taken into account in the above description. If the power supplied to the electricity grid becomes negative, i. the electrical consumers draw power from the electricity network 6 because the photovoltaic power is too low or too many consumers are switched on or the heat pump is operated at too high a power level, then the control unit shuts down according to consumers or reduces the heat pump's power consumption until the power consumed by the grid drops to zero or the minimum value.
FIG. 2 shows a schematic block diagram of a control unit 35 4 according to the invention for a photovoltaic system 1 according to FIG. 1. The control unit 4 comprises the actual control unit 4. * * * * * 4 * * * * «# * · · * • t · · · * * *
• # * * # * I • * * ♦ »Β · * ·· ··· · ·« ««
9 50047 Ag / FI
Logotherm Regelsysteme GmbH lent controller 19, one or more electrical switching stages 20 for driving external external consumers, a control input 17, a control output 18 and provided with terminals 24 power supply 21 and an electronic unit 22 and a user interface 23. The control input 17 receives the control signal 5 from Power meter (connection 10), and the control output 18 adjusts the power consumption of the first electrical load 5 (connection 11 to the heat pump). Other modules that are generally used for such control units and known in the art were not drawn for reasons of clarity. 10
3 shows a schematic flow diagram of a method according to the invention for controlling a photovoltaic system 1 according to the invention. First, the power P "" transmitted to the public electricity grid 6 is measured. If this value is greater than 0 (or greater than a certain preset target value), then 15 is first queried as to whether the electric heat pump (or another first electrical consumer 5) has already reached the maximum power level. If this is not the case, the power of the electric heat pump (of the first electrical load 5) is increased. 20 It is further provided that the electrical power of the first electrical load 5 is reduced when the power transmitted to the electricity network 6 is negative, that is, when the system receives electrical energy from the network. This is the case when the power Pnetz transmitted to the public electricity network 6 is less than zero. Then electrical loads are switched off or the power consumption of the heat pump is reduced.
Optionally, it may also be provided that the electric heat pump is operated only in a certain optimum range. If the power of the electric heat pump is at a maximum, or in the optimum range, so that no adjustment can or should take place, further electrical consumers 25 are switched on. Thereafter, the measurement of the power delivered into the network 7 takes place again, and the cycle begins again from the beginning until the power delivered into the network has reached the target value, in particular the value 0. Again, it is contemplated that electrical loads will be shut off when the power delivered to the grid is negative, ie, electrical power is sourced from the electricity grid. · «·· * ·
10
50047 Ag / FI Logotherm Regelsysteme GmbH
4 shows a schematic block diagram of an alternative embodiment of the device according to the invention. In this embodiment, a rechargeable battery 27 is additionally provided, which allows a longer-term island operation of Vorrich-5 device. The battery 27 supplies on the one hand via the inverter 28, the e-lektrische useful power Pnu * 30, which is seen as additional useful power to the already existing, supplied by the photovoltaic module 2 useful power 30. On the other hand, the battery 27 can be charged via a charger with battery monitor 26. For this purpose, the charger is supplied with battery monitor 26 with electric charge battery charging circuit 29.
The inverter 28 is designed to be adjustable in its performance and is connected via the connection for power control 34 to the control unit 4. Thus, the control unit can adjust what electrical power the battery 27 outputs as useful power 15 Pisiutz '30 to the budget. Furthermore, the charger with battery monitor 26 supplies on the one hand via the connection for battery monitor 32 the current state of charge of the battery 27 to the control unit 4, and on the other hand, the charger with battery monitor 26 via the connection 33 of the control unit 4 is set so that in the presence of excess power this Surplus power for charging 20 of the battery 27 is used.
The power consumed by the battery and delivered is supervised and recorded by the control unit 4. The minimum and maximum charge state can be set, and if the minimum charge state 25 is undershot, the inverter 28 is switched off in order to increase the battery life.
Furthermore, a connection for power failure detection 35 is provided, which detects a failure of the public electricity network 6 and supplies to the control unit 4. In this case, the inverter 28 can maintain the household power supply 30 via the battery 27.
5 shows a schematic block diagram of the control unit 4 of the embodiment according to the invention from FIG. 4. The control unit 4 has, in addition to the exemplary embodiment from FIG. 2, a plurality of control inputs 17 and control outputs 11
50047 Aft / FI Logotherm Control Systems GmbH 18 in order to enable a connection to the input connections 10, 32 and 35 or the output connections 33, 34 and 11.
It can be inventively provided that the target value is time-dependent, so-that, for example, at certain times electrical energy to be transmitted to the electricity network 6, while this is to be avoided at other times. E-benso the connection of the electrical load 25 or the battery 27 can be timed or according to a priority list. The corresponding program logic can be implemented by the control unit 4 according to the invention and is also part of the invention.

权利要求:
Claims (22)
[1]
1. Photovoltaic system (1) with at least one photovoltaic module (2), at least one inverter (3) and at least one control unit (4), wherein the photovoltaic system (1) for feeding at least a first electrical Consumer (5) and a public electricity network (6) is executed, characterized in that a power meter (8) is provided and the control unit (4) for controlling the first electrical load (5) recorded electrical power (9) is executed.
[2]
2. Photovoltaic system (1) according to claim 1, characterized in that the power meter (8) is designed both for measuring the electrical power supplied to the electrical network (6), as well as for measuring the electric power (6) related electrical power.
[3]
3. Photovoltaic system (1) according to claim 1 or 2, characterized in that a first connection (10) of the power meter (8) with the control unit (4) for transmitting the power to the electricity network (7) output power, and a second connection (11 ) of the control unit (4) with the first electrical load (5) for regulating the power consumption of the first electrical load (5) is provided.
[4]
4. Photovoltaic system according to one of claims 1 to 3, characterized in that it is the first electrical load (5) is a heat pump, an electrical heating resistor, an electrical charger o-the like.
[5]
5. Photovoltaic system (1) according to one of claims 1 to 4, characterized in that the first electrical load (5) with a buffer memory (15), for example, a hot water tank is connected. 13 50047 Ag / FI Logotherm Regelsysteme GmbH
[6]
6. Photovoltaic system according to one of claims 1 to 5, characterized in that the control unit (4) for use of excess power (12) with at least one second electrical load (25), in particular an electric heating element (13), an electrical charging station ( 14) or an electrically rechargeable battery.
[7]
7. photovoltaic system (1) according to one of claims 1 to 6, characterized in that an electrically rechargeable battery pack (27) and an associated, the battery pack (27) charging, controllable by the control unit (4), the state of charge of the battery salt ( 27) delektierendes charger with battery monitor (26) is provided.
[8]
8. Photovoltaic system (1) according to claim 7, characterized in that the battery pack (27) via a by the control unit (4) power controllable inverter (28) is designed for delivering electrical power to an electrical household network.
[9]
9. photovoltaic system (1) according to claim 7 or 8, characterized in that the charger with battery monitor (26) for receiving electrical power from the photovoltaic module (2) and for charging the battery pack (27) is executed.
[10]
10. Photovoltaic system (1) according to one of claims 7 to 9, characterized in that a power failure detection is provided.
[11]
11. Photovoltaic system (1) according to any one of claims 7 to 10, characterized in that the battery pack (27) serves as an uninterruptible power supply and supplied certain, preferably ranked by a consumer list in a power failure with electrical energy.
[12]
12. control unit (4) for a photovoltaic system (1) according to one of claims 1 to 11. »· ·· * ··» · «* ···· ·: ιϊ ι::: * . · • a * «T« * «· ♦ · ** · **« · · · · 14 50047 Ag / Π Logotherm Regelsysteme GmbH
[13]
13, control unit (4) according to claim 12, characterized in that the control unit (4) comprises a control input (17), a control output (18), a controller (19) and at least one electrical switching stage (20).
[14]
14. Control unit (4) according to claim 12 or 13, characterized in that the control unit (4) comprises a power supply (21), an electronic unit (22) and a user interface (23).
[15]
15. A method for controlling the from a photovoltaic system (1) to a first io electrical consumer (5) and to a public electricity network (6) from given electrical power, characterized in that the electric power network (6) transmitted electrical power ( 7) is measured and the power consumption of the first electrical load (5) is adjusted until the electric power 16 delivered into the electricity network (6) reaches a predetermined value, in particular the value zero,
[16]
16. The method according to claim 1415, characterized in that, if necessary, in addition at least a second electrical load (25) is supplied with electrical power until the electrical network (6) output electric power 20 reaches a predetermined value, in particular the value zero.
[17]
17. The method according to claim 15 or 16, characterized in that, if necessary, electric power is discharged via a charger with battery monitor (26) to a rechargeable battery pack (27). 25
[18]
18. The method according to any one of claims 15 to 17, characterized in that, if necessary, electrical power via a power controllable inverter (28) from the battery pack (27) for use in an electrical household network can be removed. 30
[19]
19. The method according to any one of claims 15 to 18, characterized in that in case of failure of a public electricity network (6) of the inverter (28) via the battery pack (27) maintains the electricity supply in island operation 35

15 J0047 Ag / FI Logothenn Regelsysteme GmbH
[20]
20. The method according to any one of claims 15 to 19, characterized in that the charger with battery monitor (26) monitors the charge state of the battery pack (27) and transmits to the control unit (4) and the control unit (4) falls below a battery-specific charge minimum 5 values of the battery (27) switches off the inverter (28).
[21]
21. The method according to any one of claims 17 to 20, characterized in that the battery pack (27) serves as an uninterruptible power supply and certain, preferably ranked by a priority consumer in io a power failure supplied with electrical energy, in particular a. in the case of desired high efficiency, the battery pack is discharged to a minimum at night, or b. in the case of desired high power failure safety of the battery pack is always maintained at a minimum charge level. 15
[22]
22. The method according to any one of claims 15 to 21, characterized in that the power consumption of the electrical consumers (5, 25, 13, 14, 26) takes place after a pre-determined priority list and / or is maintained in a predetermined optimum range. 20 25 Vienna, on - * hb. volume

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法律状态:
2017-05-15| PC| Change of the owner|Owner name: DAFI GMBH, AT Effective date: 20170412 |

优先权:

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申请号 | 申请日 | 专利标题

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AT21022010A|AT510882A1|2010-12-21|2010-12-21|PHOTOVOLTAIC SYSTEM|

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ATA145/2011A|AT510938B1|2010-12-21|2011-02-03|PHOTOVOLTAIC SYSTEM|ATA145/2011A| AT510938B1|2010-12-21|2011-02-03|PHOTOVOLTAIC SYSTEM|

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EP11193783.5A| EP2469238A3|2010-12-21|2011-12-15|Photovoltaic device|