WO2011120311A1 - 太阳能光发电系统、控制装置及控制方法 - Google Patents

太阳能光发电系统、控制装置及控制方法 Download PDF

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Publication number
WO2011120311A1
WO2011120311A1 PCT/CN2010/079748 CN2010079748W WO2011120311A1 WO 2011120311 A1 WO2011120311 A1 WO 2011120311A1 CN 2010079748 W CN2010079748 W CN 2010079748W WO 2011120311 A1 WO2011120311 A1 WO 2011120311A1
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Prior art keywords
output
conversion
energy
series
electric energy
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PCT/CN2010/079748
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English (en)
French (fr)
Inventor
陈道深
魏刚
李泉
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华为技术有限公司
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Publication of WO2011120311A1 publication Critical patent/WO2011120311A1/zh

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Classifications

    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02JCIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
    • H02J1/00Circuit arrangements for dc mains or dc distribution networks
    • H02J1/10Parallel operation of dc sources
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02JCIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
    • H02J3/00Circuit arrangements for ac mains or ac distribution networks
    • H02J3/38Arrangements for parallely feeding a single network by two or more generators, converters or transformers
    • H02J3/381Dispersed generators
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02JCIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
    • H02J3/00Circuit arrangements for ac mains or ac distribution networks
    • H02J3/38Arrangements for parallely feeding a single network by two or more generators, converters or transformers
    • H02J3/46Controlling of the sharing of output between the generators, converters, or transformers
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02JCIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
    • H02J2300/00Systems for supplying or distributing electric power characterised by decentralized, dispersed, or local generation
    • H02J2300/20The dispersed energy generation being of renewable origin
    • H02J2300/22The renewable source being solar energy
    • H02J2300/24The renewable source being solar energy of photovoltaic origin
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02JCIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
    • H02J2300/00Systems for supplying or distributing electric power characterised by decentralized, dispersed, or local generation
    • H02J2300/20The dispersed energy generation being of renewable origin
    • H02J2300/22The renewable source being solar energy
    • H02J2300/24The renewable source being solar energy of photovoltaic origin
    • H02J2300/26The renewable source being solar energy of photovoltaic origin involving maximum power point tracking control for photovoltaic sources
    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02MAPPARATUS FOR CONVERSION BETWEEN AC AND AC, BETWEEN AC AND DC, OR BETWEEN DC AND DC, AND FOR USE WITH MAINS OR SIMILAR POWER SUPPLY SYSTEMS; CONVERSION OF DC OR AC INPUT POWER INTO SURGE OUTPUT POWER; CONTROL OR REGULATION THEREOF
    • H02M7/00Conversion of ac power input into dc power output; Conversion of dc power input into ac power output
    • H02M7/003Constructional details, e.g. physical layout, assembly, wiring or busbar connections
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E10/00Energy generation through renewable energy sources
    • Y02E10/50Photovoltaic [PV] energy
    • Y02E10/56Power conversion systems, e.g. maximum power point trackers

Definitions

  • the present invention relates to the field of solar energy technologies, and in particular, to a solar photovoltaic power generation system, a control device, and a control method.
  • BACKGROUND OF THE INVENTION Solar energy, as a clean and renewable energy source, is playing an increasingly important role in today's increasingly global energy sources.
  • solar photovoltaic power generation is a main way of using solar energy, and its basic principle is to use solar energy cells to convert light energy into electrical energy.
  • a schematic diagram of a solar photovoltaic power generation system includes a solar cell array, a control unit, and the like; wherein, the solar cell array is used to convert light energy into electrical energy, and the solar cell is made of a material having a photovoltaic effect (Photovoltaic Effect) (for example, a silicon compound can convert light energy into electrical energy. Since the conversion efficiency of the solar cell is low, in order to achieve a large output power, it is generally required to form a solar cell array for photoelectric conversion by a large number of solar cells.
  • the control unit is used to complete the control of the entire system, including receiving the output power of the solar array and performing energy conversion, such as DC-DC (DC-DC), DC-AC (DC-AC), etc., and the converted electric energy.
  • energy conversion such as DC-DC (DC-DC), DC-AC (DC-AC), etc.
  • Output to power units such as household appliances, factories, power grids, etc.
  • the control unit is also used to complete other control of the system, such as monitoring, management and other control of the system.
  • FIG. 2 is a schematic structural diagram of a widely used solar photovoltaic power generation system in the prior art, the system includes a solar cell array, a junction box, an energy conversion controller, and the like; the most basic unit of the solar cell array is a solar cell ( Not shown in the figure), a plurality of solar cells constitute a solar photovoltaic module (PV module, Photovoltaic component, such as PV1-1, PV3-2 and the like in FIG. 2); and a plurality of PV modules constitute a solar cell array.
  • PV module solar photovoltaic module
  • PV module Photovoltaic component, such as PV1-1, PV3-2 and the like in FIG. 2
  • a plurality of PV modules constitute a solar cell array.
  • junction box and the energy conversion controller are equivalent to the control unit in FIG. 1, wherein the junction box is used for converging the output of the solar array, and outputting the converged power to the energy conversion controller; according to system design requirements
  • multiple photovoltaic modules can be connected in series to form a voltage required for one output, which can be more
  • the photovoltaic modules in series are connected to the current required for parallel output; for example, in Figure 2, the junction box will be the first, second, and third PV modules (the first corresponds to PV1-X in the figure, X represents the natural number, and the rest Several ways are the same) Parallel to be used as one output;
  • the fourth, fifth and sixth PV modules are connected in parallel and output as another.
  • the energy conversion controller is used to receive the output of the junction box and perform energy conversion, such as DC-DC conversion, or DC-AC conversion, to output the voltage required by the power unit.
  • FIG. 3 a schematic diagram of power output after the solar cell is blocked in the PV module, wherein the horizontal axis represents the output voltage of the PV component, and the vertical axis represents the power of the power; the curve 101 is the power output curve during normal operation, and the curve 102 and 103 are curves when occlusion occurs at different positions.
  • the normal working curve 101 can reach an output power of about 590W when outputting 60V; the occlusion curve 102 can only reach 360V at 60V; the occlusion (the occlusion position is different from 102) occurs.
  • a curve 103 can only reach about 80W. Therefore, when a solar cell is blocked in a PV module, it will affect the performance of the entire component. If a solar cell is completely blocked, the power loss of the entire PV module will become larger (more than 50%); It will affect the output of multiple PV modules in series and the PV modules in series and then output in parallel (output characteristics are similar to Figure 2), resulting in a decrease in power output of the entire array.
  • Embodiments of the present invention provide a solar photovoltaic power generation system, a control device, and a control method for implementing output of better performance electrical energy, wherein:
  • a solar photovoltaic system includes:
  • a combined control unit configured to receive multiple electrical energy outputted by the solar cell array, detect an output characteristic of the multiple electrical energy, and perform dynamic combination adjustment and output on the multiple electrical energy according to the output characteristic One or more electric energy;
  • the energy conversion unit is configured to receive one or more electric energy outputted by the combined control unit, perform energy conversion, and output energy converted energy.
  • a solar photovoltaic power generation system control device is configured to control the output power of the solar cell array, including:
  • a detecting unit configured to receive multiple electrical energy outputted by the solar cell array, and detect characteristics of the multiple electrical energy
  • a switch component configured to perform a series-parallel connection combination on the multiple power sources
  • a combination processing unit configured to, according to the characteristic of the multi-channel electric energy detected by the detecting unit, control the switch component to perform dynamic combination adjustment of the multi-channel electric energy in series and/or parallel according to the characteristic, and output one way or Multiple channels of electrical energy.
  • a solar photovoltaic power generation system control method comprises the following steps:
  • Receiving multi-channel electric energy outputted by the solar cell array detecting characteristics of the multi-channel electric energy; performing serial and/or parallel dynamics on the multi-channel electric energy according to the characteristic according to the characteristic of the multi-channel electric energy detected Combined adjustment, output one or more power.
  • the embodiment of the invention detects the characteristics of the output energy of the solar cell array, and performs dynamic combination adjustment of the electric energy in series and/or parallel according to the electric energy characteristics, and performs energy conversion through the energy conversion unit, which can make various situations appearing in the system. Dynamic combination adjustment for better output power.
  • Figure 1 is a schematic diagram of the working principle of the solar photovoltaic power generation system
  • FIG. 2 is a schematic structural view of a conventional solar photovoltaic power generation system
  • Figure 3 is a schematic diagram showing the power output of the PV module at different output voltages when the solar cell power generation system is in normal operation and the solar cell is blocked;
  • FIG. 4 is a schematic structural view of a solar photovoltaic power generation system according to an embodiment of the present invention.
  • FIG. 5 is a schematic diagram of connection of input power through a switch according to an embodiment of the present invention.
  • FIG. 5A is a schematic diagram of a series connection of input power through a switch according to an embodiment of the present invention.
  • 5B is a schematic diagram of parallel connection of input power through a switch according to an embodiment of the present invention.
  • 6A is a schematic diagram of combined adjustment of input power with similar characteristics according to an embodiment of the present invention
  • 6B is a schematic diagram of combined adjustment of input power with failure according to another embodiment of the present invention
  • 6C is a schematic diagram showing parallel connection of input electrical energy according to another embodiment of the present invention.
  • FIG. 7A is a schematic structural diagram of an energy conversion unit according to another embodiment of the present invention.
  • FIG. 7B is a schematic structural diagram of another energy conversion unit according to another embodiment of the present invention.
  • FIG. 8 is a schematic structural view of a solar photovoltaic power generation system according to another embodiment of the present invention.
  • FIG. 8A is a schematic diagram of an equivalent of a switching device according to another embodiment of the present invention.
  • 9A is a schematic diagram of combined adjustment of characteristic similar input power according to another embodiment of the present invention.
  • FIG. 9B is a schematic diagram of a combined adjustment of a faulty input power according to another embodiment of the present invention.
  • 9C is a schematic diagram of a series connection of input electrical energy according to another embodiment of the present invention.
  • 9D is a schematic diagram showing parallel connection of input power according to another embodiment of the present invention.
  • Figure 10 is two equivalent connections of the series circuit shown in Figure 9C;
  • FIG. 11 is a schematic structural view of a solar photovoltaic power generation system control device according to an embodiment of the present invention.
  • FIG. 12 is a schematic flow chart of a method for controlling a solar photovoltaic power generation system according to an embodiment of the present invention. DETAILED DESCRIPTION OF THE INVENTION The present invention will be further described in detail below with reference to the specific embodiments and the accompanying drawings.
  • the embodiment of the invention provides a solar photovoltaic power generation system, which is used for dynamically combining and adjusting the output of the solar cell array to obtain better performance power output, including:
  • a combined control unit configured to receive multiple electrical energy outputted by the solar cell array, detect an output characteristic of the multiple electrical energy, and perform dynamic combination adjustment and output on the multiple electrical energy according to the output characteristic One or more electric energy;
  • the energy conversion unit is configured to receive one or more electric energy outputted by the combined control unit, perform energy conversion, and output energy converted energy.
  • each output of the solar cell array is outputted by connecting a plurality of photovoltaic PV modules in series, or is outputted by connecting a plurality of PV modules connected in series in parallel.
  • the output voltage can be increased; by paralleling the PV modules, the output current can be increased; in parallel, in order to ensure reliable performance, it is necessary to select several PV modules with the same characteristics for parallel connection.
  • the combined control unit performs dynamic serial combination and/or parallel combination adjustment according to the characteristic, and outputting one or more powers includes one or a combination of the following:
  • the foregoing adjustment may be performed according to various application scenarios, for example, when there is occlusion of the PV component, one or more PV components that are occluded are output as one way; or when a short circuit occurs, the short circuit is turned off. Or electric energy; or in the case of low light, multi-channel electric energy is connected in series for output; so that the solar photovoltaic power generation system obtains superior performance output electric energy.
  • series and/or parallel refers to either series connection or parallel connection, or both series connection and parallel connection; in the following, for convenience of description, series and parallel connection are also used to indicate series connection and/or parallel connection. Unless otherwise stated, the two refer to the same meaning and are not strictly distinguished.
  • the combined control unit includes:
  • a detecting unit configured to receive the multi-channel electric energy outputted by the solar cell array, and detect the characteristics of the multi-channel electric energy; wherein the detected content includes a voltage and a current; and the voltage and current values determine whether the electric energy characteristics of the respective circuits are similar or Whether there is a malfunction.
  • the switch component may specifically include a plurality of switching units, and each of the switching units may be a metal oxide semiconductor MOS (Metal Oxide Semiconductor) metal oxide semiconductor tube. Or insulated gate type power transistor IGBT (Insulated Gate Bipolar Transistor) devices, or devices with switching characteristics such as controllable relays.
  • MOS Metal Oxide Semiconductor
  • IGBT Insulated Gate Bipolar Transistor
  • a processing unit configured to: according to the characteristic of the multi-channel electric energy detected by the detecting unit, control the switch component to perform dynamic combination adjustment of the multi-channel electric energy in series and/or parallel according to the characteristic, and output one or more Road energy.
  • the processing unit should set the time interval for dynamic combination adjustment to be smaller, for example, every 1 second or 2 seconds.
  • the energy conversion unit in the embodiment of the present invention includes one or more conversion modules, and each conversion module includes one conversion channel or multiple conversion channels.
  • the design can be symmetrically designed, that is, each conversion module has the same conversion capability; or an asymmetric design, that is, multiple conversion modules or conversion channels with different capabilities, depending on the conversion capability of each conversion module or conversion channel.
  • the power to be converted is allocated in a certain proportion, for example, a module or channel with high conversion capability allocates multiple points of input power, a module with weak conversion capability or a channel with less input power. By proportionally, the load carried by each conversion module or conversion channel is not too large or too small, which makes the system load more balanced.
  • the embodiment of the invention detects the multi-channel electric energy characteristics of the solar cell array output by the combined control unit, and parallels the multiple electric energy having similar characteristics into one output according to the multi-channel electric energy characteristic, and disconnects the faulty electric energy to avoid the problematic electric energy pair.
  • the entire electric energy is affected; at the same time, the multiple electric energy can be connected in series, so that the solar photovoltaic power generation system of the embodiment of the invention can output the voltage required by the system under the condition of low light and the like, thereby improving the utilization rate of the optical energy.
  • the energy conversion unit of the embodiment of the present invention uses a symmetric or asymmetric manner to design an energy conversion module or a conversion channel; when there is less energy to be converted, turning off one or more conversion or conversion channels that do not need to participate in the conversion may reduce The power consumption of the system.
  • Embodiment 2
  • the embodiment of the present invention provides a solar photovoltaic power generation system for improving energy conversion efficiency.
  • the solar cell array 41, the combination control unit 42 and the energy conversion unit 43 are included.
  • the solar cell array 41 outputs M power.
  • the combined control unit performs dynamic combination control after the combined control unit outputs N energy to the energy conversion unit for energy conversion and outputs to the power unit; where M is generally greater than N, for example, M is generally greater than 4, and N Usually 2 or 3, etc.
  • the embodiments of the present invention include:
  • a solar cell array 41 for outputting one or more electric energy
  • the most basic unit in a solar cell array is a solar cell.
  • the solar cell is composed of a material having a photovoltaic effect, which can convert light energy into electric energy. Since a single solar cell outputs less electric energy, in order to meet a large output electric energy demand, it is required A plurality of solar cells are connected in series to form a PV module (or a solar cell module). At the same time, in order to achieve more power output, multiple PV modules can be connected in series to increase the single output voltage; multiple PV modules (each PV module or multiple PV modules are connected in series) are connected in parallel to increase the output current.
  • the output voltage of each channel can be the same, or different, for example:
  • the first route is 2 PV modules connected in series, the output is 96V voltage (48V output per PV component), and the second route is connected in series with 3 PV modules.
  • Output 144V voltage when the first output current is not enough, it can be improved by connecting in parallel with a PV module with an output voltage of 96V.
  • Output current In practical applications, solar arrays generally use PV modules of the same specification. Therefore, if the first path needs to increase the output current, it can be realized by paralleling exactly the same way. It should be noted that the output of each PV module described above is required.
  • the rating (such as 48V) is the output under certain lighting conditions, does not mean that the output is 48V in any lighting situation; for example, in the rainy days with weaker light, early morning, evening, etc., this value will not be reached, and At noon in summer when there is plenty of light, the output will exceed this value. Therefore, during operation, the set voltage of the PV component is a dynamically changing value, but as long as the voltage is within the range required by the back end energy conversion unit (eg, 90V-110V), the output power can be energy converted. Make the output.
  • the combination control unit 42 is configured to receive multiple electrical energy outputted by the solar cell array 41, detect an output characteristic of the multiple electrical energy, and perform dynamic combination adjustment of the multiple electrical energy in series and/or parallel according to the output characteristic. , output one or more channels of electrical energy;
  • the combination control unit includes a switch component 421, a detection unit 422, and a processing unit 423.
  • the switch component 421 is composed of a plurality of switch units, each of which is composed of a device (switching device) having a switching characteristic, such as MOS. (Metal Oxide Semiconductor) A device, an IGBT (Insulated Gate Bipolar Transistor) device, or a controllable relay.
  • the switching device includes a control terminal that can be used to control whether the device is turned on or off, thereby achieving an effect similar to a switch. In the actual application process, the appropriate switching device can be selected according to the performance parameters of the system, or the driving circuit can be combined to meet the design requirements of the system.
  • a schematic diagram of serial-parallel combination of input power (1, 2 channels shown in the figure) is performed by using a plurality of switch units, wherein the switch unit K3 is used to determine whether the 1st and 2nd channels are connected; Kl, K2, K4 , k5 is used to determine whether 1, 2 or 2 channels are output to the corresponding output terminals (Pout l , Pout2 ), and each switch unit receives a control signal from the processing unit to determine whether to open an account or close.
  • the series-parallel connection is combined with the input of multiple powers; so that multiple powers can increase the output voltage through series connection, and can also increase the output current by paralleling.
  • FIG. 5A a schematic diagram of outputting 1, 2 channels in series from the Pout l terminal is shown.
  • the control signals are used to control K3 and ⁇ 4 to be turned off, and the remaining switches are turned on, so that the 1 and 2 channels can be connected in series and outputted from the Poutl terminal;
  • the control signals are used to control K1 and ⁇ 4 to be turned off, and the remaining switches are turned on. It is possible to realize the parallel connection of the 1 and 2 channels from the Poutl terminal.
  • the detecting unit 422 is configured to receive the multi-channel electric energy outputted by the solar cell array, and detect the output characteristics of each electric energy, for example, by detecting the magnitude of the voltage and the magnitude of the current to detect whether the characteristics of each road are similar, whether the circuit is open, whether it is short-circuited, or the like.
  • the processing unit 423 is configured to acquire the power output characteristics of the respective outputs output by the detecting unit, and perform dynamic combination adjustment of the multiple powers in series and/or parallel according to the output characteristics of the respective powers, and output one or more powers.
  • the combination adjustment is dynamically performed in real time, and the processing unit actively acquires the information detected by the detection unit at regular intervals (eg, 500 milliseconds, 1 second, 2 seconds, etc.) or Receiving the information reported by the detecting unit to obtain the power output characteristics of each channel, determining the state of the solar cell array (for example, a certain performance degradation, or several faults, etc.), and serially connecting the multiple power sources according to the state. / or parallel dynamic combination adjustment.
  • the processing unit A22 can be implemented by using a chip or a hardware circuit having a processing function, for example, a CPU (Central Processing Unit), an MCU (Micro Control Unit), and a DSP (Digital). Signal Processor, Digital Signal Processor) and other control chips or hardware circuits with similar functions.
  • a CPU Central Processing Unit
  • MCU Micro Control Unit
  • DSP Digital Signal Processor
  • the detecting unit 422 and the processing unit 423 are not strictly distinguished. In the actual application process, the two units can use the same processing chip, for example, the same CPU chip is used together, and some pins of the chip are used as input of the detecting unit. , other pins as the output of the processing unit.
  • the processing unit 423 performs serial and/or parallel dynamic combination adjustment on multiple power sources by controlling the switch unit. Specifically, by controlling the control terminal of the switch unit, the switching device is turned on or off, thereby controlling each output. The output or disconnection of electrical energy, or a combination of series-parallel connection.
  • the processing unit 423 performs serial and/or parallel dynamic combination adjustment of multiple power sources mainly including one or several of the following combinations:
  • FIG. 6A the left picture is a schematic diagram of normal operation, where the arrows indicated by numbers 1-6 indicate the output by the solar array.
  • the road electric energy, the arrows indicated by the letters A and B, indicate the multi-channel electric energy outputted to the energy conversion unit by the combined control unit for serially and/or parallel dynamic combination adjustment of the above-mentioned multi-channel electric energy.
  • the combined control unit parallels 1, 2, and 3 input powers into one output to the energy conversion unit, and parallels 4, 5, and 6 input powers into one output to the energy conversion unit;
  • the 2nd channel and the 4th channel are connected in parallel for one channel; the 1, 3, 5, and 6 channels are connected in parallel for one channel for output; wherein, the 2nd and 4th channels are Both are occluded for PV modules, they have similar electrical characteristics; the first, third, fifth, and sixth paths are all in normal operation, and they have similar electrical characteristics.
  • the “similarity” here can be understood as the similarity within a certain error.
  • 100V can be considered similar to 98V, 95V, 102V; or 100V and 90V, 110V in another error range. Think similar.
  • Faults here include short circuits, open circuits, severe voltage or current shortages, etc.
  • a PV component failure it can affect the output, stability, and safety of the entire system. Therefore, it is necessary to detect in real time whether the power of each circuit is faulty. If an abnormal situation is detected, such as an excessive current or a voltage is too small, the power needs to be disconnected from the combined control unit to avoid affecting the entire system. .
  • a short-circuit protection circuit can be provided on the hardware to prevent the system from being affected when a short circuit occurs. See Figure 6B.
  • the left figure shows the system during normal operation.
  • the figure on the right shows the disconnection of the 5th channel from the combined control unit.
  • the fault information may be notified to the relevant maintenance personnel through various communication modes (including wired communication or wireless communication), so that the maintenance personnel can obtain the fault information.
  • the faulty equipment is repaired or replaced.
  • Sending fault information can also be applied to the situation where the PV component is blocked, and the maintenance personnel are notified by sending a fault message to clear the relevant obstruction.
  • the left figure is a schematic diagram of the system during normal operation
  • the right figure is a schematic diagram of connecting the input multiple powers in low light to increase the output voltage.
  • the multi-channel electric energy is also output as a series to increase the output voltage.
  • the embodiment of the invention detects the multi-channel electric energy characteristics of the solar array output in real time, and combines multiple powers of similar characteristics, disconnected faulty output electric energy, serial-parallel multi-output electric energy, etc. according to the electric energy characteristics.
  • the way can be one of them, or a combination of several), so that the system always runs in a good working state.
  • the energy conversion unit 43 is configured to receive one or more powers output by the combined control unit, perform energy conversion, and output energy converted energy.
  • the combined control unit dynamically adjusts the output of the solar array, one or more powers are output.
  • the combined control unit generally outputs multiple channels of power; in the case of weak light, etc., which need to increase the output voltage and current, multiple channels can be connected in series or in parallel.
  • Energy conversion includes DC-DC (DC-DC), DC-AC (DC-AC), DC voltage regulation, etc., in which DC-D (:, DC-AC, etc. conversion can be used to convert high voltage At low voltage, the low voltage can also be converted to a high voltage.
  • DC-D DC-AC, etc. conversion can be used to convert high voltage
  • the low voltage can also be converted to a high voltage.
  • each channel can also perform energy conversion using an interleave method to improve the efficiency of energy conversion.
  • the energy conversion using the Interleave method is a technique well known to those skilled in the art, and Let me repeat.
  • the energy conversion unit includes one or more conversion modules, where each conversion module includes one conversion channel or multiple conversion channels, and the specific implementation may generally include the following:
  • FIG. 7A a schematic diagram of performing energy conversion when a plurality of single modules are used, and each module has only one conversion channel; the power conversion capabilities of the plurality of conversion modules may be the same or different.
  • an asymmetric conversion module configuration may be adopted, that is, a configuration method combining a large and small power conversion module is adopted: a high power channel outputted by combining the combined control units is connected to a high power conversion module; The small power channel outputted by combining the combination control unit is connected to the small power conversion module; in some application situations (for example, in the case of low light), the high power conversion module may be omitted, and only the small power conversion module is used, due to small The power conversion module itself consumes less power than the high power conversion module consumes. Therefore, turning off (or sleeping) the high power conversion module and using only the small power conversion module can reduce the power consumption of the system.
  • FIG. 7B a schematic diagram of energy conversion using a conversion module; the conversion module integrally includes a plurality of energy conversion channels, each of which can have the same or different energy conversion capability, and the channel energy conversion capability is large.
  • the combination of the control unit is combined with the output of the high-power channel; the channel energy conversion capability is small and connected to the small power channel output by the combined control unit; similar to the energy conversion of multiple conversion modules, because the conversion channel with small capacity level The power consumed is small. Therefore, in some applications, the conversion channel with a large capability level can be omitted, and only the conversion channel with a small level can be used to reduce the power consumption of the system.
  • one module is used, one of which is a single module and the other is a conversion module with multiple conversion channels.
  • the power to be converted can be proportionally distributed according to the conversion capability, so that the system load is more balanced.
  • one or more conversion modules or conversion channels that do not need to participate in conversion can be turned off to reduce the power consumption of the system; when switching the conversion module or conversion channel, in two conversion modules or conversion Under the premise that the channel can meet the conversion, the one that consumes a large power (usually a conversion module or conversion channel with strong conversion capability) can be turned off.
  • the embodiment of the present invention provides a solar photovoltaic power generation system based on the foregoing embodiment 2, including: a solar cell array 81, a combination control unit 82, and an energy conversion unit 83;
  • the solar cell array 81 is composed of a plurality of PV modules connected in series and in parallel.
  • the structure of the PV module has been described in the background art and will not be described herein. Wherein, connecting multiple PV modules in series can increase the output voltage; connecting multiple PV modules in parallel can increase the output current.
  • connecting multiple PV modules in parallel can increase the output current.
  • Paralleling a single PV component with similar voltage characteristics (or multiple PV components after series) should be selected. Parallel connection, if the voltage characteristics of the two channels connected in parallel are different, the performance of the circuit after the parallel connection will be degraded.
  • the solar cell array 81 is composed of a plurality of PV modules connected in series, wherein the PV modules 1-1 to 1-N1 represent the first way; the PV components 2-1 to 2-N2 represent the second Road, the other roads are represented by a similar method; the figure shows five PV modules connected in series, the number of practical applications is not limited, and the number of PV modules can be increased or decreased according to application requirements.
  • the method of expressing the electric energy by using two positive and negative line segments in FIG. 2 is changed to use one line segment to indicate positive and negative, it should be understood that those skilled in the art can According to this representation method, the actual circuit is correctly connected.
  • the number of PV modules connected in series is not fixed, and a certain number of PV modules can be connected in series according to the requirements of the system for output voltage. For example, assuming that each PV component outputs 20V, if you need to output 100V, you can connect five PV components in series. To output 40V, you only need to connect two PV components in series.
  • the number of PV modules connected in series is usually the same for ease of management and maintenance.
  • FIG. 8 in the embodiment of the present invention, it is assumed that there are a total of five PV modules connected in series, and each output is composed of the same type and the same number of PV modules connected in series, wherein, in order to increase the output current, the 1 and 2 channels are connected in parallel. Then output, so that the total power output to the combined control unit is 4 channels, which are A, B, C, and D roads respectively.
  • a route 1 and 2 roads are connected in parallel
  • B road corresponds to 3 roads
  • C road Corresponding to 4 channels
  • D channel corresponds to 5 channels.
  • the combination control unit 82 of the embodiment of the present invention includes a detecting unit 821, a processing unit 822, and a plurality of switching units K1-K11.
  • the combined control unit receives four channels of electric energy (A, B, C, D) output from the solar array, and after dynamic combination control, outputs two electric energy (E, F) to the energy conversion unit.
  • the input 4 channels of electric energy form a combined switching network through a plurality of switch units K1-K11, so that multiple lines of electric energy can form various series-parallel connection combinations to dynamically adjust the input electric energy; wherein, Kl, ⁇ 2, ⁇ 3 are used for Set whether two adjacent input powers are connected in series, and K4-K11 is used to set whether each input power is input to the corresponding output (E, F).
  • each switching unit can be completed by using a component having a switching effect such as a MOSFET, an IGBT, or a relay. Referring to FIG.
  • the left figure is a schematic diagram of the MOS device, including the gate (G), the drain (D), and the source (S); the right figure is equivalent to converting the MOS device into a switch.
  • Switching devices require matching devices to be selected based on system characteristics.
  • additional circuits such as driver circuits, protection circuits, etc. can be added to meet system performance requirements.
  • the detection unit first detects the characteristics of the input electrical energy (for example, determining whether an occlusion, a short circuit, an open circuit, etc. occurs according to the voltage and current values); and then the detection unit obtains the detection according to the detection unit.
  • the result is a combined adjustment of the input power, including:
  • the C channel can be used as a single output; Several normal working powers are used as the other output; for example, if the C channel is output through the F channel and the A, B, and D channels are output through the E channel (parallel), the state of each switching unit can be controlled as:
  • the occluded electric energy can be separately output as the other way, and the original two channels are still output as one way.
  • the switch related to the C path can be disconnected.
  • the C path is disconnected; meanwhile, the A and B channels are output in parallel to the E.
  • the D channel is output to F separately, the status of each switch unit can be controlled as follows:
  • the processing unit may also notify the console or maintenance personnel through the communication interface 723 (including wired or wireless mode) to update the device; at the same time, the processing unit may also receive the command from the console or the maintenance command, Various input powers are combined and adjusted.
  • FIG. 9C a schematic diagram of outputting all of A, B, C, and D in series, at this time, the processing unit controls the switching states of the respective switching units as follows:
  • K4 ⁇ 5, ⁇ 6, ⁇ 7, ⁇ 8, ⁇ 10, K11 are open;
  • the switching state setting of the above switching unit it is possible to make the output of B, C, D in series, and the output voltage is equal to the sum of the voltages of the respective circuits.
  • the schematic diagram of the embodiment of the present invention simplifies one power (including the positive pole and the negative pole) into one line segment, the positive and negative poles of the power source are not represented. It can be understood that, depending on the definition of the polarity, it can also be considered Turn ⁇ 9 on, ⁇ 7 off and output.
  • the above two different polarities can be referred to FIG. 10, wherein the left diagram in FIG. 10 corresponds to the application of the ⁇ 9 closing ,9, and the opening ⁇ 7; the right drawing in FIG. 10 is equivalent to the application of opening ⁇ 9, closing ⁇ 7
  • the connection setting of the positive and negative poles of the power source is a technique well known to those skilled in the art, and details are not described herein again.
  • the above detection and adjustment are performed in real time, for example, every 1 second or 2 seconds, and by detecting and adjusting the combination of each input electric energy in real time, it is possible to respond to the situation in which the problem occurs in time.
  • the present invention by detecting the multi-channel electric energy characteristics of the solar array output in real time, and combining the multi-channel electric energy of similar characteristics according to the electric energy characteristics, and by disconnecting the output electric energy of the fault, it is possible to avoid problems such as occlusion and malfunction of a certain road.
  • the influence of the whole system By connecting multiple electric energy in series or in parallel to output, it is possible to output the electric energy required by the energy conversion unit in the case of insufficient light such as rainy days, early mornings, and evenings, thereby improving the utilization efficiency of the light energy. Increased the output of electrical energy.
  • the energy conversion unit 73 is configured to receive one or more electric energy outputted by the combined control unit, perform energy conversion, and output the energy converted energy.
  • the conversion module of the energy conversion unit can use various existing or unknown energy conversion modules to complete energy conversion such as DC_DC and DC-AC, and output the converted power to the power consumption unit.
  • the energy conversion unit may implement energy conversion through multiple conversion modules or conversion modules having multiple conversion channels, or may combine the two to achieve energy conversion.
  • the embodiment of the present invention uses two conversion modules to implement energy conversion, and the conversion capabilities of the two conversion modules are not the same, but one of the conversion modules preferably has a larger conversion capability than the maximum output of the solar array, so that even if another When a conversion module is not working, energy conversion to the output power of the solar array can also be realized.
  • the two modules are generally not in the state of full load operation, but the power to be converted is allocated according to a certain proportion.
  • the conversion module with strong conversion capability is connected to the power of the combined control unit to output large power (accounting for The conversion power needs to be converted to a large proportion.
  • the conversion module with weak conversion capability is connected to the combined control unit to output small power (which accounts for a small proportion of the energy to be converted), which makes the system load more balanced.
  • the conversion module 1 has a maximum conversion power of 2000W, and the other conversion module has a maximum conversion power of 1000W.
  • the two convert the power to be converted in a ratio of 7:3. Assuming that the solar array can output 1800W when the system is working normally, the conversion module 1 converts 7/10 of the 1800W, and the conversion module 2 converts 3/10 of the 1800W.
  • the system needs to convert less power (such as in rainy days, early mornings, evenings, etc.), one of them can be turned off (or hibernated) to reduce the power consumption of the system.
  • the conversion module 1 can be turned off, and only the conversion module 2 can be used for operation; if the power to be converted is 1200W, the conversion module 2 can be turned off, and only the conversion module 1 can be used for work (here In this case, you can also work together two).
  • the embodiment of the present invention provides a solar photovoltaic power generation system control device.
  • the method includes: a detecting unit 111, configured to receive multiple electrical energy outputted by the solar cell array, and detect characteristics of the multiple electrical energy;
  • a switch component 112 configured to perform a series-parallel connection combination on the multiple power sources
  • the combination processing unit 113 is configured to, according to the characteristic of the multi-channel electric energy detected by the detecting unit, control the switch component to perform dynamic combination adjustment of the multi-channel electric energy in series and/or parallel according to the characteristic, and output one way Or multiple channels of electrical energy.
  • the combination processing unit 113 performs serial and/or parallel dynamic combination adjustment on the multiple powers, and outputs one or more powers including one or a combination of the following:
  • the characteristics of the multi-channel electric energy detected by the detecting unit include the voltage and current of the electric energy; the voltage or current within a certain error range can be considered to be similar, and if the voltage of a certain electric energy is seriously decreased, the road can be considered as The power has failed.
  • the detection unit detects the characteristics of the electric energy in real time, so that the fault can be responded to as soon as possible, and the characteristics of the combined processing unit to obtain each electric energy can be obtained by actively acquiring or receiving the report of the detecting unit.
  • the switch assembly 112 in the embodiment of the present invention includes a plurality of switch units 114 for performing series-parallel connection and combination of multiple power sources, so that multiple power sources can increase the output voltage through series connection, and can also increase the output current by parallel connection.
  • the switching unit can be a device having a switching characteristic such as a MOSFET, an IGBT device, or a controllable relay. For details, refer to the description of the switching unit in the above embodiment, and details are not described herein again.
  • the combination processing unit acquires characteristics of the multi-channel electric energy detected according to the detecting unit, and performs dynamic combination adjustment of the multi-channel electric energy in series and/or parallel, specifically performing various combination adjustments by controlling opening or closing of the plurality of switching units Specifically, the following one or several application scenario combinations may be included:
  • the combined processing unit may parallel the one or more powers that appear to be blocked into one way for output, and the rest.
  • the normal working power is connected in parallel for the other way to output;
  • the combined processing unit can control the switch unit to disconnect the failed power from the output to avoid affecting the performance of the entire system;
  • the combined processing unit can connect multiple powers in series to output the required voltage.
  • the above dynamic combination adjustment is performed in real time, and the specific interval time can be set smaller (such as 1 second or 2 seconds) in order to respond to the situation of the system in time.
  • the embodiment of the present invention performs dynamic combination adjustment mode for one or more of the above situations by detecting various electric energy characteristics, so that the entire system can avoid the occurrence of a decrease in performance of the entire system due to a problem of one or several output powers; At the same time, multi-channel power is output in series when the light is weak, and the output voltage is increased to meet the system's demand for voltage.
  • Embodiment 5 may exist in the form of a separate device, or may be designed to be located in a junction box of an existing solar photovoltaic power generation system in order to be compatible with existing devices.
  • Embodiment 5 may exist in the form of a separate device, or may be designed to be located in a junction box of an existing solar photovoltaic power generation system in order to be compatible with existing devices.
  • Embodiments of the present invention provide a solar photovoltaic power generation system control method, as shown in FIG. 12, including:
  • the S12K receives the multi-channel electric energy outputted by the solar cell array, and detects characteristics of the multi-channel electric energy
  • S122 Perform, according to the characteristic, the serial power and/or the parallel dynamic combination adjustment of the multiple powers according to the characteristics of the detected multiple powers, and output one or more powers.
  • the multi-channel electric energy is serially and/or parallelly dynamically combined and adjusted, and outputting one or more electric energy includes:
  • Multi-channel power is used as a unit for serial output.
  • the characteristics of detecting multi-channel electric energy include detecting the voltage and current of the electric energy; the voltage or current within a certain error range can be considered to be similar, and if the voltage of a certain electric energy is seriously decreased, it can be considered as The road energy has failed. At the same time, the characteristics of the detected electrical energy are performed in real time, so that the fault can be responded as soon as possible.
  • Performing series and/or parallel dynamic combination adjustment of multiple powers is accomplished by switching a plurality of switching units in the switch assembly, and a plurality of the plurality of switching units are used to serially connect the outputs of the solar array
  • the combination allows multiple power sources to increase the output voltage in series, as well as increase the output current in parallel.
  • the switching unit can be a device having a switching characteristic such as a MOSFET, an IGBT device, or a controllable relay.
  • the series and/or parallel dynamic combination adjustment of the multi-channel electric energy is performed by controlling the opening or closing of the plurality of switching units to perform various combination adjustments, including one or a combination of the following applications:
  • the switch unit can be controlled to disconnect the failed power from the output to avoid affecting the performance of the entire system;
  • the embodiment of the invention obtains the dynamic combination adjustment manner for the above one or several situations in real time by acquiring various electric energy characteristics in real time, so that the whole system can avoid the performance degradation of the whole system due to the problem of one or several output electrical energy. Occurs; At the same time, when the light is weak, multi-channel power is output in series to increase the output voltage to meet the system's demand for voltage.
  • the above control method can be implemented based on the system or device in the above embodiment, or can also be implemented by using a hardware entity having a similar function.
  • a person skilled in the art can understand that all or part of the process of implementing the above embodiment method can be completed by a computer program to instruct related hardware, and the program can be stored in a computer readable storage medium. In execution, the flow of an embodiment of the methods as described above may be included.
  • the storage medium may be a magnetic disk, an optical disk, a read-only memory (ROM), or a random access memory (RAM).

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Description

太阳能光发电系统、 控制装 ¾¾控制 本申请要求于 2010年 4月 1日提交中国专利局、 申请号为 201010142337. 8、 发明 名称为 "太阳能发光电系统、 控制装置及控制方法"的中国专利申请的优先权, 其全部 内容通过引用结合在本申请中。 技术领域 本发明涉及太阳能技术领域, 尤其涉及一种太阳能光发电系统、 控制装置及控制方 法。 背景技术 太阳能作为一种清洁可再生能源, 在全球能源日益紧张的今天, 正发挥着越来越重 要的作用。 其中, 太阳能光发电是利用太阳能的一种主要方式, 其基本原理是利用太阳 能电池将光能转换成电能。
参见图 1, 为太阳能光发电系统的原理示意图, 包括太阳能电池阵列、 控制单元等 部分; 其中, 太阳能电池阵列用于将光能转化为电能, 太阳能电池由具有光伏效应 (Photovoltaic Effect ) 的材料 (如硅化合物) 构成, 可以将光能转化为电能, 由于 太阳能电池的转化效率较低, 为了达到大的输出功率, 一般都需要将大量的太阳能电池 组成太阳能电池阵列来进行光电转换。
控制单元用于完成对整个系统的控制, 包括接收太阳能电池阵列的输出电能, 并进 行能量转换, 如 DC-DC (直流-直流), DC-AC (直流-交流) 等, 将转换后的电能输出给 用电单元 (如家用电器、 工厂、 电网等); 此外, 控制单元也用于完成对系统的其他控 制, 如对系统的监控、 管理等控制。
参见图 2, 为现有技术中一种广泛使用的太阳能光发电系统结构示意图, 该系统包 括太阳能电池阵列、 汇线盒、 能量转换控制器等单元; 太阳能电池阵列的最基本单元是 太阳能电池(图中未示出),多个太阳能电池组成太阳能光伏组件 (PV组件, Photovoltaic 组件, 如图 2中 PV1-1、 PV3-2等单元); 多个 PV组件组成太阳能电池阵列。
汇线盒以及能量转换控制器相当于图 1中的控制单元, 其中, 汇线盒用于对太阳能 电池阵列输出进行汇合, 并将汇合后的电源输出给能量转换控制器; 根据系统的设计要 求, 在太阳能电池阵列中, 可以将多个光伏组件串联成一路输出需要的电压, 可以将多 路串联的光伏组件进行并联输出需要的电流; 例如, 在图 2中, 汇线盒将第一、 二、 三 路光伏组件 (第一路对应于图中的 PV1-X, X表示自然数, 其余几路类同) 并联后作为 一路输出; 将第四、 五、 六路光伏组件并联后作为另一路输出。
能量转换控制器用于接收汇线盒的输出,并进行能量转换,如 DC-DC转换,或 DC-AC 转换, 输出用电单元所需的电压。
发明人在实现本发明的过程中, 发现现有技术至少存在以下缺点:
在图 2所示的太阳能光发电系统中, 如果 PV组件中的一个或多个太阳能电池出现 被物体遮挡的情况, 则会对整个 PV组件的功率输出产生很大影响。 参见图 3, 为 PV组 件中出现太阳能电池被遮挡后功率输出示意图, 其中, 图中横轴表示 PV组件的输出电 压, 纵轴表示功率的功率; 曲线 101为正常工作时的功率输出曲线, 曲线 102以及 103 为在不同位置出现遮挡时的曲线。 以输出电压为 60V为例, 正常工作的曲线 101在输出 60V时能达到 590W左右的输出功率;出现遮挡的曲线 102在 60V时只能达到 360V左右; 出现遮挡 (遮挡位置与 102不同) 的另一曲线 103则只能达到 80W左右。 因此, 当 PV 组件中有太阳能电池被遮挡时, 会对整个组件的性能造成影响, 如果一个太阳能电池被 完全遮挡, 则整个 PV组件的功率损失会变得更大 (超过 50%) ; 进而还会影响多个串联 的 PV组件输出以及多个串联的 PV组件再进行并联后的输出 (输出特征与图 2类似), 造成整个阵列的功率输出下降。
此外, 如果有阴影遮挡, 或者在其他光照较弱的情况时, 会因为 PV组件输出电压 过低而无法让能量转换控制器进行工作, 从而造成电能的浪费。 发明内容
本发明实施例提供一种太阳能光发电系统、 控制装置及控制方法, 用于实现更优性 能电能的输出, 其中:
一种太阳能光电光系统包括:
太阳能电池阵列, 用于输出多路电能;
组合控制单元, 用于接收所述太阳能电池阵列输出的多路电能, 检测所述多路电能 的输出特性, 根据所述输出特性对所述多路电能进行串联和 /或并联动态组合调整, 输 出一路或多路电能;
能量转换单元,用于接收所述组合控制单元输出的一路或多路电能,进行能量转换, 输出能量转换后的电能。 其中,一种太阳能光发电系统控制装置,用于对太阳能电池阵列输出电能进行控制, 包括:
检测单元, 用于接收太阳能电池阵列输出的多路电能, 对所述多路电能的特性进行 检测;
开关组件, 用于对所述多路电能进行串并联连接组合;
组合处理单元, 用于根据所述检测单元检测得到的所述多路电能的特性, 根据所述 特性控制所述开关组件对所述多路电能进行串联和 /或并联动态组合调整, 输出一路或 多路电能。
其中, 一种太阳能光发电系统控制方法, 包括如下步骤:
接收太阳能电池阵列输出的多路电能, 对所述多路电能的特性进行检测; 根据检测得到的所述多路电能的特性, 根据所述特性对所述多路电能进行串联和 / 或并联动态组合调整, 输出一路或多路电能。
本发明实施例通过检测太阳能电池阵列输出电能的特性, 并根据电能特征对各路电 能进行串联和 /或并联动态组合调整, 通过能量转换单元进行能量转化, 可以对系统出 现的各种情况做出动态组合调整, 获得更优性能的输出电能。 附图说明 为了更清楚地说明本发明实施例中的技术方案, 下面将对实施例或现有技术描述中 所需要使用的附图作简单地介绍, 显而易见地, 下面描述中的附图仅仅是本发明的一些 实施例, 对于本领域普通技术人员来讲, 在不付出创造性劳动的前提下, 还可以根据这 些附图获得其他的附图。
图 1为太阳能光发电系统工作原理示意图;
图 2为现有太阳能光发电系统结构示意图;
图 3为现有太阳能光发电系统中正常工作及有太阳能电池出现遮挡时, PV组件在不 同输出电压下功率输出示意图;
图 4为本发明实施例太阳能光发电系统结构示意图;
图 5为本发明实施例通过开关对输入电能进行连接示意图;
图 5A为本发明实施例通过开关对输入电能进行串联示意图;
图 5B为本发明实施例通过开关对输入电能进行并联示意图;
图 6A为本发明实施例当对特性相似输入电能进行组合调整示意图; 图 6B为本发明另一实施例对出现故障的输入电能进行组合调整示意图;
图 6C为本发明另一实施例对输入电能进行并联示意图;
图 7A为本发明另一实施例能量转换单元结构示意图;
图 7B为本发明另一实施例另一能量转换单元结构示意图;
图 8为本发明另一实施例太阳能光发电系统结构示意图;
图 8A为本发明另一实施例开关器件等效示意图;
图 9A为本发明另一实施例对特性相似输入电能进行组合调整示意图;
图 9B为本发明另一实施例对出现故障的输入电能进行组合调整示意图;
图 9C为本发明另一实施例对输入电能进行串联示意图;
图 9D为本发明另一实施例对输入电能进行并联示意图;
图 10为图 9C所示串联电路的两种等效接法;
图 11为本发明实施例太阳能光发电系统控制装置结构示意图;
图 12为本发明实施例太阳能光发电系统控制方法流程示意图。 具体实 ¾ ^式 为使本发明的目的、 技术方案及优点更加清楚明白, 以下将通过具体实施例和相关 附图, 对本发明作进一步详细说明。
实施例一
本发明实施例提供一种太阳能光发电系统,用于通过对太阳能电池阵列的输出进行 动态组合调整, 获得更优性能的电能输出, 包括:
太阳能电池阵列, 用于输出多路电能;
组合控制单元, 用于接收所述太阳能电池阵列输出的多路电能, 检测所述多路电能 的输出特性, 根据所述输出特性对所述多路电能进行串联和 /或并联动态组合调整, 输 出一路或多路电能;
能量转换单元,用于接收所述组合控制单元输出的一路或多路电能,进行能量转换, 输出能量转换后的电能。
其中, 太阳能电池阵列每路输出由多个光伏 PV组件串联后输出, 或者由多组串联后 的 PV组件并联后输出。 通过串联 PV组件, 可以提高输出电压; 通过并联 PV组件, 可以提 高输出电流; 在并联时, 为了保证性能的可靠, 需要选择特征相同的几种 PV组件进行并 联。 本发明实施例中, 所述组合控制单元根据所述特性对所述多路电能进行串联和 /或 并联动态组合调整, 输出一路或多路电能包括以下其中一种或几种组合:
将性能相似的多路电能并联成一路输出; 或者,
关断发生故障的电能输出; 或者,
将多路电能串联成一路输出。
具体的, 可以根据各种应用场景进行上述调整, 例如, 当有 PV组件出现遮挡时, 将 出现遮挡的一种或多路 PV组件作为一路进行输出; 或者当发生短路时, 关断这路短路的 电能; 或者在弱光的情况下将多路电能串联成一路进行输出; 使得太阳能光发电系统获 得更优性能的输出电能。
需要说明的是, 上述串联和 /或并联指的是既可以串联, 也可以是并联, 或者既包 括串联又包括并联; 在下文中, 为了描述方便, 也用串并联来表示串联和 /或并联, 如 无特殊说明, 两者所指代的为同一意思, 并不严格区分。
具体的, 本发明实施例中, 组合控制单元包括:
检测单元, 用于接收太阳能电池阵列输出的多路电能, 对所述多路电能的特性进行 检测; 其中, 检测的内容包括电压、 电流; 通过电压、 电流的值判断各路电能特性是否 相似或是否出现故障。
开关组件, 用于对所述多路电能进行串并联连接组合; 开关组件具体可以包括多个 开关单元, 每个开关单元可以为金属氧化物半导体 MOS (Metal Oxide Semiconductor) 金属氧化物半导体) 管, 或者绝缘栅极型功率管 IGBT ( Insulated Gate Bipolar Transistor, 绝缘栅极型功率管) 器件, 或者可控继电器等具有开关特征的器件。
处理单元, 用于根据所述检测单元检测得到的所述多路电能的特性, 根据所述特性 控制所述开关组件对所述多路电能进行串联和 /或并联动态组合调整, 输出一路或多路 电能。
为了及时对系统出现的各种状态做出响应, 处理单元在进行动态组合调整时的时间 间隔应设置得小一点, 例如每隔 1秒或 2秒进行一次调整。
本发明实施例中的能量转换单元包括一个或多个转换模块,每个转换模块包括一个 转换通道或多个转换通道。 在设计时可以采用对称设计, 即每个转换模块的转换能力相 同; 或者也可以采用非对称设计, 即采用多个具有不同能力的转换模块或转换通道, 根 据各个转换模块或转换通道的转换能力按一定比例分配需要转换的电能, 例如, 转换能 力强的模块或通道分配多点的输入电能, 转换能力弱的模块或通道分配少点的输入电 能, 通过按比例分配, 每个转换模块或转换通道所承载的负载不至于过大或过小, 可以 使得系统负载更加均衡。
当需要转换的电能较少时, 关闭一个或多个不需要参与转换的转换或转换通道; 例 如, 如果一个小模块能够处理所有的转化功能时, 可以将需要转换的电能都接入至该小 模块, 关闭 (或休眠) 不需要参与转换的模块或通道, 以降低系统的功耗。
本发明实施例通过组合控制单元检测太阳能电池阵列输出的多路电能特性,根据多 路电能特性将多路具有相似特性的电能并联为一路输出,将出现故障的电能断开可以避 免有问题电能对整个电能造成影响; 同时, 还可将多路电能进行串联, 这样使得本发明 实施例太阳能光发电系统在弱光等条件下也能输出系统所需的电压, 提高了光能利用 率。
此外,本发明实施例能量转换单元采用对称或非对称方式来设计能量转换模块或转 换通道;当需要转换的电能较少时,关闭一个或多个不需要参与转换的转换或转换通道, 可以降低系统的功耗。 实施例二
本发明实施例提供一种太阳能光发电系统, 用于提高能量转换效率, 参见图 4, 包 括太阳能电池阵列 41、 组合控制单元 42以及能量转换单元 43 ; 其中, 太阳能电池阵列 41 输出 M路电能给组合控制单元, 经组合控制单元进行动态组合控制后输出 N路电能给能量 转换单元进行能量转换后输出给用电单元; 这里的 M—般都大于 N, 例如 M—般取大于 4, 而 N—般为 2或 3等。
具体的, 本发明实施例包括:
太阳能电池阵列 41, 用于输出一路或多路电能;
太阳能电池阵列中最基本的单元为太阳能电池,太阳能电池由具有光伏效应的材料 构成, 可以将光能转化为电能; 由于单个太阳能电池输出的电能较小, 为了满足大的输 出电能需求时, 需要将多个太阳能电池进行串联构成 PV组件 (或称太阳能电池组件) 。 同时, 为了达到更多的电能输出, 可以将多个 PV组件串联以提高单路输出电压; 将多路 PV组件 (每路由一个 PV组件或多个 PV组件串联) 并联以提高输出电流。
在进行多路输出时, 每路的输出电压可以相同, 或者不同, 例如: 第一路由 2个 PV 组件串联, 输出 96V电压 (每个 PV组件输出 48V ) , 第二路由 3个 PV组件串联, 输出 144V 电压; 当第一路输出电流不够时, 可以通过与一路输出电压为 96V的 PV组件并联来提高 输出电流。 在实际应用中, 太阳能电池阵列一般采用相同规格的 PV组件, 因此, 如果第 一路需要提高输出电流, 可以通过并联与其完全相同的一路来实现; 需要说明的是, 上 述每个 PV组件的输出额定值 (如 48V) 是在特定光照情况下的输出, 并不代表任何光照 情况下都输出为 48V; 例如, 在光照较弱的阴雨天、 清晨、 傍晚等时候会达不到这个值, 而在夏季光照充足的中午, 输出会超过这个值。 因此, 在工作过程中, PV组件的组出电 压是一个动态变化的值, 但只要电压在后端能量转换单元所要求的范围内 (如 90V-110V) , 都可以将输出电能进行能量转换后进行输出。
本发明实施例还包括:
组合控制单元 42, 用于接收所述太阳能电池阵列 41输出的多路电能, 检测所述多路 电能的输出特性,根据所述输出特性对所述多路电能进行串联和 /或并联动态组合调整, 输出一路或多路电能;
参见图 4, 组合控制单元包括开关组件 421, 检测单元 422, 处理单元 423; 其中, 开 关组件 421由多个开关单元组成, 每个开关单元由具有开关特性的器件 (开关器件) 构 成, 例如 MOS (Metal Oxide Semiconductor) 金属氧化物半导体) 管、 IGBT ( Insulated Gate Bipolar Transistor, 绝缘栅极型功率管) 器件、 或者可控继电器等。 开关器件 包括一个控制端, 可以用于控制该器件是否导通或截止, 从而实现类似于一个开关的效 果。 实际应用过程中, 可以根据系统的性能参数选择合适的开关器件, 或者再通过结合 驱动电路来满足系统的设计需求。
参见图 5, 为利用多个开关单元对输入电能 (图中所示 1、 2路) 进行串并联组合示 意图, 其中, 开关单元 K3用于决定 1、 2路是否进行连接; Kl、 K2、 K4、 k5用于决定 1、 2 路是否输出到对应的输出端 (Pout l , Pout2 ) , 各个开关单元都接收来自处理单元的控 制信号, 以决定是否开户或关闭。
通过设置多个开关单元, 以多路电能的输入进行串并联连接组合; 使得多路电能既 能通过串联提高输出电压, 也能通过并联提高输出电流。
参见图 5A, 表示将 1、 2路串联从 Pout l端输出的示意图, 通过控制信号控制 K3、 Κ4 关闭, 其余开关打开, 可以实现将 1、 2路串联后从 Poutl端输出;
参见图 5B, 表示将 1、 2路并联从 Pout2端输出的示意图, 通过控制信号控制 Kl、 Κ4 关闭, 其余开关打开, 可以实现将 1、 2路并联后从 Poutl端输出。 检测单元 422用于接收太阳能电池阵列输出的多路电能,检测各路电能的输出特性, 例如通过检测电压的大小, 电流的大小来检测各路特征是否相似、 是否断路、 是否短路 等。 处理单元 423用于获取检测单元输出的各路电能输出特性, 根据各路电能的输出特 性, 对所述多路电能进行串联和 /或并联动态组合调整, 输出一路或多路电能。 为了更 好地对系统出现的状态做出响应, 这种组合调整为动态实时进行的, 处理单元每隔一定 时间 (如 500毫秒、 1秒、 2秒等) 通过主动获取检测单元检测的信息或接收检测单元上 报的信息来获取各路电能输出特征, 判断所述太阳能电池阵列所处的状态(例如某几路 性能下降、 或几路发生故障等) , 并根据状态对多路电能进行串联和 /或并联动态组合 调整。
在具体电路实现上, 处理单元 A22可以采用具有处理功能的芯片或硬件电路实现, 例如可以采用 CPU ( Central Processing Unit , 中央处理器) 、 MCU (Micro Control ler Unit , 微处理单元) 、 DSP (Digital Signal Processor, 数字信号处理器) 等控制芯 片或具有类似功能的硬件电路实现。
需要说明的是, 检测单元 422及处理单元 423并不严格区分, 在实际应用过程中, 两 个单元可以使用同一处理芯片, 例如, 共同使用同一 CPU芯片, 芯片的一些引脚作为检 测单元的输入, 另一些引脚作为处理单元的输出。 此外, 当使用处理芯片进行检测、 控 制时, 由于芯片一般都采用数字电平 (电压较小, 如 3-5V) , 与太阳能电池阵列的输出 电平 (电压较大, 如几十伏到几百伏) 并不兼容, 因此, 需要通过相关处理电路将太阳 能电池阵列的输出电平转换成处理芯片能够兼容的电平, 例如, 通过限幅调理电路(如 电阻降压)来完成这种转换。 这些处理电路的设计为本领域技术人员所熟知的技术, 在 此不再赘述。
处理单元 423对多路电能进行串联和 /或并联动态组合调整通过控制开关单元来实 现, 具体的, 通过控制开关单元的控制端, 使得开关器件出现导通或截止的特性, 进而 控制各路输出电能的输出或断开, 或者进行串并联连接关系的组合。
参见图 6A、 6B、 6C, 处理单元 423对多路电能进行串联和 /或并联动态组合调整主要 包括以下几种一种或几种组合:
( 1 ) 将性能相似的多路电能并联成一路输出;
这种情况一般应用在其中某些 PV组件中的太阳能电池有被遮挡的情况; 参见图 6A, 左图为正常工作时的示意图, 其中数字 1-6表示的箭头表示由太阳能电池阵列输出的多 路电能, 字母 A、 B表示的箭头表示组合控制单元对上述多路电能进行串联和 /或并联动 态组合调整后输出到能量转换单元的多路电能。 在正常工作时, 组合控制单元将 1、 2、 3路输入电能并联为一路输出到能量转换单元, 将 4、 5、 6路输入电能并联为一路输出到 能量转换单元;
假设在使用过程当中, 第 2、 4路中的 PV组件出现了被遮挡的情况 (例如, 被树叶、 土石、 动物排泄物、 动物尸体等遮挡) , 则这几路的输出特性会发生改变 (如电压、 电 流值减小) ; 这种情况下需要对这几路输出电能进行组合调整, 将特性相似的几路输出 电能作为一路进行输出。 参见图 6A右图, 在 2、 4路出现遮挡的情况下将 2路和 4路并联为 一路进行输出; 将 1、 3、 5、 6路并联为一路进行输出; 其中, 第 2、 4路都为 PV组件出现 遮挡的情况, 它们具有相似的电能特性; 第 1、 3、 5、 6路均处于正常工作的状态, 它们 具有相似的电能特性。
这里的"相似"可以理解为在一定误差内的相似, 例如, 根据系统设计参数的要求, 可以将 100V与 98V、 95V、 102V认为是相似; 或者在另一误差范围内将 100V与 90V、 110V 认为相似。
将特性相似的电能作为一路并联后输出可以降低因并联特性不相似的支路而造成 的功率损失。
( 2 ) 关断发生故障的电能输出;
这里的故障包括短路、 断路、 电压或电流严重不足等情况; 在 PV组件出现故障的情 况下, 其对整个系统的输出、 稳定性、 安全性都会造成影响。 因此, 需要实时检测各路 电能是否发生故障, 如果检测到异常情况, 如电流过大, 或电压过小等异常情况, 需要 将该路电能从组合控制单元中断开, 以免对整个系统造成影响。
另外, 还可以在硬件上设置短路保护电路, 以防止发生短路时对系统造成影响。 参见图 6B, 左图为系统正常工作时的示意图, 右图为第 5路出现故障时将其从组合 控制单元中断开的示意图。
在本发明实施例中, 当控制单元发现输出的电能有故障时, 还可以通过各种通信方 式 (包括有线通信或无线通信)将故障信息告知相关维护人员, 使得维护人员得到故障 信息后能对故障的设备进行维修或更换。发送故障信息同样也可以应用在 PV组件出现遮 挡的情况, 通过发送故障信息通知维护人员清除相关的遮挡物。
此外, 由于很多太阳能光发电系统都处于人烟稀少, 环境条件相对较恶劣的地区, 维护一次需要付出的成本较高; 因此, 还可以根据收集的故障信息, 在故障的器件达到 一定数量, 或者比较严重时再去现场一次性完成对所有的设备的维护, 具体可以根据实 际情况选择维护的时机。
( 3 ) 将多路电能串联成一路输出;
这种情况一般应用在弱光的情况下, 如在阴雨天、 清晨或傍晚阳光相对较弱的情况 下,单路 PV组件无法输出需要的电压或电流,而后端的能量转换单元如果需要正常工作, 其输入的电压必须达到一定的值, 因此, 当 PV组件输出较低时, 将导致能量转换单元无 法正常工作, 也就将光能转化为电能, 从而造成能量的浪费。 此时, 可以将若干路 PV组 件进行串联, 以提高输出电压, 使得能量转换单元能够正常工作。
其中, 串联时对多路电能各自的电压并无特别严格的要求, 一种比较好的应用场景 是将多路幅值相似的电压进行串联后输出。
参见图 6C, 左图为系统正常工作时的示意图, 右图为在弱光时对输入的多路电能进 行串联以提高输出电压的示意图。
将多路电能作为一路进行输出的情况并不只是在弱光的情况下可以应用,在其他需 要电压特征进行改变的情况下也将多路电能作为一路进行串联输出, 以增加输出电压。
需要说明的是, 上面几种情况也可以进行组合调整, 例如, 在第 (3 ) 种情况的基 础上, 如果还需要提高输出电流, 则还可以将串联后电压相同的几路 PV组件进行并联, 以提高输出电流。
本发明实施例通过实时检测太阳能阵列输出的多路电能特性, 并根据电能特性对其 进行合并相似特性的多路电能、 断开出现故障的输出电能、 串并联多路输出电能等多种 动态调整方式 (可以是其中一种, 或几种的组合) , 使得系统始终运行在一个良好的工 作状态。
本发明实施例还包括:
能量转换单元 43, 用于接收所述组合控制单元输出的一路或多路电能, 进行能量转 换, 输出能量转换后的电能。
经过组合控制单元对太阳能电池阵列的输出进行动态组合调整后,输出一路或多路 电能。 在正常工作情况下, 或者有遮挡情况下, 组合控制单元一般都会输出多路电能; 在弱光等需要提高输出电压、 电流的情况下, 可以将多路串联或并联成一路进行输出。
能量转换包括直流 -直流(DC-DC ) 、 直流 -交流(DC-AC ) 、 直流稳压等处理, 其中, 在进行 DC-D (:、 DC-AC等变换时, 既可以将高电压变换成低电压, 也可以将低电压变换成 高电压。 能量转换单元进行能量转换时, 每一路还可以采用交错 (Interleave )方式进行能 量转换, 以提高能量转换的效率, 其中, 用 Interleave方式进行能量转换为本领域技术 人员所熟知的技术, 在此不再赘述。
能量转换单元包括一个或多个转换模块, 其中, 每个转换模块包括一个转换通道或 多个转换通道, 具体实现方式通常可以包括以下几种:
( 1 ) 多个转换模块进行能量转换
参见图 7A, 为采用多个单模块, 且每个模块只有一个转换通道时进行能量转换的示 意图; 多个转换模块的功率转换能力可以是相同, 也可以不同。 在实际应用中, 为了更 好地降低功耗, 可以采用非对称转换模块配置, 即采用大小功率转换模块结合的配置方 法: 将组合控制单元组合后输出的大功率通道与大功率转换模块相连; 将组合控制单元 组合后输出的小功率通道与小功率转换模块相连; 在某些应用情形下 (例如弱光的情 况) , 可以不使用大功率转换模块, 而只使用小功率转换模块, 由于小功率转换模块自 身消耗的功率要小于大功率转换模块消耗的功率, 因此, 关闭 (或休眠)大功率转换模 块而只使用小功率转换模块可以降低系统的功耗。
( 2 ) 一个转换模块进行能量转换
参见图 7B, 为采用一个转换模块进行能量转换的示意图; 该转换模块整体包括多个 能量转换通道, 每个能量通道进行能量转换的能力等级可以相同, 也可以不同, 通道能 量转换能力大的与组合控制单元组合后输出的大功率通道相连; 通道能量转换能力小的 与组合控制单元组合后输出的小功率通道相连; 与多个转换模块进行能量转换的情况类 似, 因为能力等级小的转换通道消耗的功率小, 因此, 在某些应用情形下, 可以不使用 能力等级大的转换通道, 而只使用等级小的转换通道, 以降低系统的功耗。
( 3 ) 以上两种情况的结合
可以结合以上两种情况, 例如采用一个两个模块, 其中, 一个为单模块, 另一个为 带有多个转换通道的转换模块。
上述几种情况存在如果不同转换能力的转换通道 (或模块) 时, 都可以按转换能力 的大小按比例分配需要转换的电能, 使得系统负载更加均衡。 同时, 在需要转换的电能 较少时, 可以关闭一个或多个不需要参与转换的转换模块或转换通道, 以降低系统的功 耗; 关闭转换模块或转换通道时, 在两个转换模块或转换通道都能满足转换的前提下, 可以关掉消耗功率大的那个 (一般为转换能力强的转换模块或转换通道) 。 实施例三
参见图 8, 本发明实施例基于上述实施例二提供了一种太阳能光发电系统, 包括: 太阳能电池阵列 81, 组合控制单元 82, 能量转换单元 83;
太阳能电池阵列 81由多个 PV组件串并联构成, PV组件的结构在背景技术中已有介 绍, 在此不再赘述。 其中, 将多个 PV组件串联可以增大输出电压; 将多个 PV组件并联可 以增大输出电流, 在并联的时候, 应该选择具有相似电压特征的单个 PV组件(或串联后 的多个 PV组件)进行并联, 如果相互并联的两路电压特征差异较大, 则会造成整个并联 后电路性能的下降。
参见图 8, 本发明实施例中太阳能电池阵列 81由多路串联后的 PV组件组成, 其中 PV 组件 1-1到 1-N1表示第 1路; PV组件 2-1到 2-N2表示第 2路, 其余几路采用类似的方法进行 表示; 图中示出了 5路串联的 PV组件, 实际应用中的数量并不限定, 可以根据应用需求 增加或减少 PV组件输出路数。 此外, 为了使图更加简洁明了, 本发明实施例中将图 2中 用正负两根线段表示输出电能的方法改为用一根线段来表示正负, 应该理解的是, 本领 域技术人员可以根据这种表示方法来对实际电路进行正确的连接。
在串联的 PV组件中, 每一路串联的 PV组件数目并不固定, 可以根据系统对输出电压 的要求串联需要一定数量的 PV组件。 例如, 假设每个 PV组件输出 20V电压, 则如需输出 100V电压, 可以串联 5个 PV组件; 如需输出 40V电压, 则只需要串联两个 PV组件。
在实际应用中, 尤其是大型发电应用时, 为了便于管理与维护, 通常各路串联的 PV 组件数量相同。 参见图 8, 本发明实施例中假设总共有 5路串联的 PV组件, 每路输出都由 相同型号且相同数量的 PV组件串联组成, 其中, 为了增加输出电流, 将 1、 2路进行并联 后再输出, 这样, 最后输出到组合控制单元的电能总共有 4路, 分别是 A、 B、 C, D路, 其中, A路由 1、 2路并联后得到, B路对应于 3路, C路对应于 4路, D路对应于 5路。
参见图 7, 本发明实施例组合控制单元 82包括检测单元 821、 处理单元 822以及多个 开关单元 K1-K11。 组合控制单元接收太阳能电池阵列输出的 4路电能 (A、 B、 C, D ) , 经动态组合控制后, 输出两路电能 (E、 F) 到能量转换单元。
输入的 4路电能通过多个开关单元 K1-K11构成一个组合切换网, 使得多路电能能够 形成各种串并联连接组合, 以对输入的电能进行动态调整; 其中, Kl、 Κ2、 Κ3用于设置 相邻的两路输入电能是否串联, K4-K11用于设置各路输入电能是否输入到对应的输出端 ( E、 F) 。 具体的, 每个开关单元可以采用 M0S管、 IGBT、 继电器等具有开关效应的元器件来 完成。 参见图 8A, 以 M0S管作为开关器件为例, 左图为 M0S器件示意图, 包括栅极 (G) 、 漏极 (D) 以及源极 (S) ; 右图为将 M0S器件等效成一个开关的示意图, 其中, 将 M0S管 的栅极 (G) 看成是控制端, 将漏极 (D) 以及源极 (S ) 看成是两个信号端。
开关器件需要根据系统特性选择相匹配的器件,此外,还可以增加一些附加电路(如 驱动电路、 保护电路等) 来满足系统要求的性能。
本发明实施例在进行动态调整过程中, 首先通过检测单元检测输入电能的特性(例 如, 根据电压、 电流值来判断是否出现遮挡、 短路、 断路等情况) ; 接着处理单元根据 检测单元得到的检测结果对输入电能进行组合调整, 包括:
( 1 ) 将特性相似的几路输出电能作为一路进行并联输出;
例如, 当 C路出现遮挡时, 这样它的输出特性会跟正常工作的 A、 B、 D路不相似(电 压、 电流出现显著下降) , 此时, 可以将 C路单独作为一路输出; 将其余几路正常工作 的电能作为另一路输出; 例如, 如果将 C路通过 F路输出, A、 B、 D路通过 E路 (并联) 输 出, 则可以控制各开关单元的状态为:
KK K2、 Κ3、 Κ5、 Κ6、 Κ8打开;
Κ4、 Κ7、 Κ9、 Κ10、 K11关闭;
最后形成的电路等效图如图 9Α所示, 即 、 B、 D路并联输出到 E; C路单独输出到 F。 通过将性能相似的电能作为一路进行输出,可以降低性能较差的一路电能对整个系统的 影响; 例如, 假设现在共有 3路电能, 正常工作时都输出 100W, 总共可输出 300W的电能; 此时, 如果有其中一路出现遮挡, 则会以整个系统的输出造成影响, 这里假设会对整个 系统造成 50%的性能下降, 则最终输出的电能总共为 300W* (1-50%) =150W; 为了减少出现 遮挡的电能对系统造成的影响, 可以将出现遮挡的电能单独作为另一路进行输出, 而原 来的两路仍作为一路进行输出, 这时, 总共输出的电能为 200W (正常工作的两路电能) + 100* (1-50%) =250W (出现遮挡的电能) , 显然, 经过调整之后, 可以输出更多的电能。
( 2 ) 将出现故障的一路从组合控制单元中断开;
例如, 当 C路出现故障需要将其断开时, 可以将跟 C路有关的开关都断开, 如本发明 实施例中, 将 C路断开; 同时, A、 B路并联输出到 E, D路单独输出到 F, 则可以控制各开 关单元的状态为:
KK K2、 Κ3、 Κ5、 Κ6、 Κ7、 Κ10、 K11打开;
Κ4、 Κ8、 Κ9关闭; 最后形成的电路等效图如图 9B所示, 即将 C路断开; A、 B路并联输出至 E; D路单独 输出到 F。 当发现有故障后, 处理单元还可以通过通信接口 723 (包括有线、 无线方式) 通知控制台或维护人员, 来对设备进行更新; 同时, 处理单元也可接收来自控制台或维 护指令, 来对各种输入电能进行组合调整。
( 3 ) 将多路电能串联作为一路进行输出;
例如, 在清晨或傍晚阳光相对较弱的情况下, 可以将几路进行串联输出; 以提高输 出电压。
参见图 9C, 为将 A、 B、 C, D全部串联后进行输出的示意图, 此时, 处理单元控制各 开关单元的开关状态如下:
K4、 Κ5、 Κ6、 Κ7、 Κ8、 Κ10、 K11打开;
Kl、 Κ2、 Κ3、 Κ9关闭;
通过上述开关单元的开关状态设置, 可以使得 、 B、 C, D串联后进行输出, 输出电 压等于各路电压之和。 由于本发明实施例示意图中将一路电能(包含正极与负极)简化 成一根线段表示, 因此, 没有将电源的正负极表示出来, 可以理解的是, 根据对极性定 义的不同, 也可以认为将 Κ9打开, Κ7关闭后进行输出。 上面两种不同极性的情况可以参 见图 10来表示, 其中, 图 10中的左图相当于 Α关闭 Κ9, 打开 Κ7的应用情况; 图 10中的右 图相当于打开 Κ9, 关闭 Κ7的应用情况, 实际应用中对电源正负极的连接设置属于本领域 技术人员所熟知的技术, 在此不再赘述。
此外, 也可以将所有的电能都并联为一路进行输出, 为了保证输出性能, 所有电能 的特性必须都相似, 这种情况也可视为图 9Α情况下的一个特例, 参见图 9D, 为将 A、 B、 C D全部并联后进行输出的示意图, 此时, 处理单元控制各开关单元的开关状态如下:
KK K2、 Κ3、 Κ5、 Κ8、 Κ10、 K11打开;
Κ4、 Κ6、 Κ7、 Κ9关闭;
通过上述开关单元的开关状态设置, 将所有输入电能全部并联输出到 Ε路, 可以增 加输入到 Ε路的工作电流。
在实际应用中, 并不需要每次都将所有的输入电能进行串联或并联, 而是根据系统 参数要求选择能满足的几路进行串联或并联即可; 如只串联或只并联其中的两路或三 路。
同时, 对于上述几种情况的具体操作可以参考实施例二中有关组合控制单元的介 绍, 在此不再赘述。 此外, 上述检测并调整为实时进行, 如每隔 1秒或 2秒进行一次, 通过实时检测并调 整各路输入电能的组合, 可以及时地对出现问题的情况做出响应。
本发明实施例通过实时检测太阳能阵列输出的多路电能特性, 并根据电能特性合并 相似特性的多路电能以及通过断开出现故障的输出电能, 可以避免因某路出现遮挡、 故 障等问题时对整个系统的影响; 通过将多路电能串联或并联成一路进行输出, 可以在阴 雨天、 清晨、 傍晚等光线不足的情况下也能输出能量转换单元所需的电能, 提高了光能 利用效率, 增加了电能的产出。
本发明实施例还包括:
能量转换单元 73, 用于接收组合控制单元输出的一路或多路电能, 进行能量转换, 输出能量转换后的电能。
能量转换单元的转换模块可以采用现有的或未知的各种能量转换模块, 完成 DC_DC、 DC-AC等能量转换, 将转换后的电能输出给用电单元。
具体的, 如实施例二中所介绍的, 能量转换单元可通过多个转换模块或具有多个转 换通道的转换模块来实现能量转换, 或者也可以将两者相结合来实现能量转换。
参见图 7, 本发明实施例采用两个转换模块来实现能量转换, 且两个转换模块的转 换能力并不相同, 但其中一个转换模块转换能力最好大于太阳能电池阵列的最大输出, 这样即使另一转换模块不工作时, 也能实现对太阳能电池阵列输出电能的能量转换。 在 正常工作时, 两个模块一般不会都处于满负荷工作的状态, 而是按一定比例分配需要转 换的电能, 具体为转换能力强的转换模块接组合控制单元输出的功率大的电能(占需要 转换电能的比例多) , 转换能力弱的转换模块接组合控制单元输出的功率小的电能(占 需要转换的电能比例少) , 这样可以使得系统负载更加均衡。
例如, 转换模块 1最大转换功率为 2000W, 而另一转换模块最大转换功率为 1000W, 两个按 7 : 3的比例分配需要转换的电能。 假设系统正常工作时太阳能电池阵列能输出 1800W, 则转换模块 1转换 1800W中的 7/10, 转换模块 2转换 1800W中的 3/10。
在另外一种情况下, 如果系统需要转换的电能较少 (如在阴雨天、 清晨、 傍晚等时 间) , 则可以关闭 (或休眠) 其中一路, 以降低系统的功耗。 例如, 需要转换的电能只 有 800W时, 可以关闭转换模块 1, 而只使用转换模块 2进行工作; 如果需要转换的电能为 1200W, 可以关闭转换模块 2, 而只使用转换模块 1进行工作 (在这种情况下也可以两个 一起工作) 。 实施例四
本发明实施例提供了一种太阳能光发电系统控制装置, 参见图 11, 包括: 检测单元 111, 用于接收太阳能电池阵列输出的多路电能, 对所述多路电能的特性 进行检测;
开关组件 112, 用于对所述多路电能进行串并联连接组合;
组合处理单元 113, 用于根据所述检测单元检测得到的所述多路电能的特性, 根据 所述特性控制所述开关组件对所述多路电能进行串联和 /或并联动态组合调整, 输出一 路或多路电能。
其中, 组合处理单元 113对所述多路电能进行串联和 /或并联动态组合调整, 输出一 路或多路电能包括以下其中一种或几种组合:
将性能相似的多路电能并联成一路输出; 或者,
关断发生故障的电能输出; 或者,
将多路电能串联成一路输出。
其中, 上述检测单元检测的多路电能的特性包括电能的电压、 电流; 可以将一定误 差范围内的电压或电流都认为是相似, 如果某路电能的电压出现严重的下降, 则可认为 这路电能发生了故障。 检测单元检测电能的特性为实时进行, 这样可以尽快对故障进行 响应, 组合处理单元获取各路电能的特性可以通过主动获取, 或接收检测单元的上报来 获取。
本发明实施例中的开关组件 112包括多个开关单元 114,用于对多路电能进行串并联 连接组合, 使得多路电能可以通过串联提高输出电压, 也能通过并联提高输出电流。 开 关单元可以采用 M0S管、 IGBT器件、 可控继电器等具有开关特性的器件, 具体可以参见 上述实施例中对开关单元的描述, 在此不再赘述。
组合处理单元获取根据检测单元检测得到的所述多路电能的特性,对所述多路电能 进行串联和 /或并联动态组合调整具体通过控制多个开关单元的打开或关闭来进行各种 组合调整, 具体可以包括以下一种或几种应用场景组合:
在出现太阳能电池被遮挡的情况下, 由于遮挡的一路或几路会造成整路甚至整个系 统的性能下降, 因此, 组合处理单元可以将出现遮挡的一路或多路电能并联成一路进行 输出, 其余正常工作的电能并联为另一路进行输出;
或者, 当发生短路、 断路、 电压或电流严重不足等故障时, 组合处理单元可以控制开关单 元将发生故障的电能与输出断开, 避免对整个系统的性能造成影响;
或者,
当在阴雨天、 凌晨、 傍晚等光照较弱, 单路无法输出足够的电压时, 组合处理单元 可以将多路电能进行串联, 以输出需要的电压。
上述动态组合调整为实时进行的,具体间隔时间可以设置得小一点(如 1秒或 2秒), 以便及时对系统出现的状况做出响应。
本发明实施例通过检测各种电能特性,针对以上一种或几种情况进行动态组合调整 方式, 使得整个系统可以避免因某一路或几路输出电能出现问题而造成整个系统性能下 降情况的发生; 同时, 在光线较弱的时候将多路电能进行串联输出, 增大输出电压, 满 足系统对电压的需求。
本发明实施例可以以单独的设备形式存在, 或者为了与现有的设备兼容, 也可以设 计成位于现有太阳能光发电系统汇线盒当中。 实施例五
本发明实施例提供了一种太阳能光发电系统控制方法, 参见图 12, 包括:
S12K 接收太阳能电池阵列输出的多路电能, 对所述多路电能的特性进行检测;
S122、 根据检测得到的所述多路电能的特性, 根据所述特性对所述多路电能进行串 联和 /或并联动态组合调整, 输出一路或多路电能。
其中, 根据所述特性对所述多路电能进行串联和 /或并联动态组合调整, 输出一路 或多路电能包括:
将性能相似的电能作为一路进行并联输出; 或者,
将发生故障的输出电能断开; 或者,
将多路电能作为一路进行串联输出。
本发明实施例中, 检测多路电能的特性包括检测电能的电压、 电流; 可以将一定误 差范围内的电压或电流都认为是相似, 如果某路电能的电压出现严重的下降, 则可认为 这路电能发生了故障。同时,检测电能的特性实时进行,这样可以尽快对故障进行响应。
对多路电能进行串联和 /或并联动态组合调整通过切换开关组件中的多个开关单元 来完成, 上述多个开关单元中的多个开关单元用于将太阳能电池阵列的输出进行串并联 组合, 使得多路电能可以通过串联提高输出电压, 也能通过并联提高输出电流。 开关单 元可以采用 M0S管、 IGBT器件、 可控继电器等具有开关特性的器件。
其中, 对多路电能进行串联和 /或并联动态组合调整具体通过控制多个开关单元的 打开或关闭来进行各种组合调整, 包括以下一种或几种应用组合:
在出现太阳能电池被遮挡的情况下, 由于遮挡的一路或几路会造成整路甚至整个系 统的性能下降, 因此, 可以将出现遮挡的几路电能并联成一路进行输出, 其余正常工作 的电能并联为另一路进行输出;
或者,
当发生短路、 断路、 电压或电流严重不足等故障时, 可以控制开关单元将发生故障 的电能与输出断开, 避免对整个系统的性能造成影响;
或者,
当在阴雨天、 凌晨、 傍晚等光照较弱, 单路无法输出足够的电压时, 可以将多路电 能进行串联, 以输出需要的电压。
本发明实施例通过实时获取各种电能特性,及时针对以上一种或几种情况进行动态 组合调整方式, 使得整个系统可以避免因某一路或几路输出电能出现问题而造成整个系 统性能下降情况的发生; 同时, 在光线较弱的时候将多路电能进行串联输出, 增大输出 电压, 满足系统对电压的需求。
上述控制方法可以基于上述实施例中的系统或设备来实现, 或者也可以采用具有类 似功能的硬件实体来实现。 本领域普通技术人员可以理解实现上述实施例方法中的全部或部分流程, 是可以通 过计算机程序来指令相关的硬件来完成,所述的程序可存储于一计算机可读取存储介质 中, 该程序在执行时, 可包括如上述各方法的实施例的流程。 其中, 所述的存储介质可 为磁碟、 光盘、 只读存储记忆体(Read-Only Memory, ROM)或随机存储记忆体(Random Access Memory, RAM) 等。
上列较佳实施例, 对本发明的目的、 技术方案和优点进行了进一步详细说明, 所应 理解的是, 以上所述仅为本发明的较佳实施例而已, 并不用以限制本发明, 凡在本发明 的精神和原则之内, 所作的任何修改、 等同替换、 改进等, 均应包含在本发明的保护范 围之内。

Claims

权利要求
1. 一种太阳能光发电系统, 其特征在于, 包括:
太阳能电池阵列, 用于输出多路电能;
组合控制单元, 用于接收所述太阳能电池阵列输出的多路电能, 检测所述多路电能 的输出特性, 根据所述输出特性对所述多路电能进行串联和 /或并联动态组合调整, 输 出一路或多路电能;
能量转换单元,用于接收所述组合控制单元输出的一路或多路电能,进行能量转换, 输出能量转换后的电能。
2. 如权利要求 1所述的太阳能光发电系统, 其特征在于:
所述太阳能电池阵列每路输出由多个光伏 PV组件串联后输出, 或者由多组串联后的
PV组件并联后输出。
3. 如权利要求 1所述的太阳能光发电系统, 其特征在于, 所述组合控制单元根据所 述输出特性对所述多路电能进行串联和 /或并联动态组合调整, 输出一路或多路电能包 括以下其中一种或几种组合:
将性能相似的多路电能并联成一路输出; 或者,
关断发生故障的电能输出; 或者,
将多路电能串联成一路输出。
4. 如权利要求 1所述的太阳能光发电系统, 其特征在于, 所述组合控制单元包括: 检测单元, 用于接收太阳能电池阵列输出的多路电能, 对所述多路电能的特性进行 检测;
开关组件, 用于对所述多路电能进行串并联连接组合;
处理单元, 用于根据所述检测单元检测得到的所述多路电能的特性, 根据所述特性 控制所述开关组件对所述多路电能进行串联和 /或并联动态组合调整, 输出一路或多路 电能。
5. 如权利要求 4所述的太阳能光发电系统, 其特征在于:
所述开关组件包括多个开关单元, 所述开关单元为金属氧化物半导体 M0S管, 或者 绝缘栅极型功率管 IGBT器件, 或者可控继电器。
6. 如权利要求 1所述的太阳能光发电系统, 其特征在于:
所述能量转换单元包括一个或多个转换模块,每个转换模块包括一个转换通道或多 个转换通道; 根据各个转换模块或者转换通道的转换能力按一定比例分配需要转换的电能。
7. 如权利要求 6所述的太阳能光发电系统, 其特征在于:
当需要转换的电能较少时, 关闭一个或多个不需要参与转换的转换模块或转换通 道。
8. 一种太阳能光发电系统控制装置, 用于对太阳能电池阵列输出电能进行控制, 其特征在于, 包括:
检测单元, 用于接收太阳能电池阵列输出的多路电能, 对所述多路电能的特性进行 检测;
开关组件, 用于对所述多路电能进行串并联连接组合;
组合处理单元, 用于根据所述检测单元检测得到的所述多路电能的特性, 根据所述 特性控制所述开关组件对所述多路电能进行串联和 /或并联动态组合调整, 输出一路或 多路电能。
9. 如权利要求 8所述的控制装置, 其特征在于, 所述组合处理单元对所述多路电能 进行串联和 /或并联动态组合调整,输出一路或多路电能包括以下其中一种或几种组合: 将性能相似的多路电能并联成一路输出; 或者,
关断发生故障的电能输出; 或者,
将多路电能串联成一路输出。
10. 如权利要求 8所述的控制装置, 其特征在于:
所述开关组件包括多个开关单元, 所述开关单元为金属氧化物半导体 M0S管, 或者 绝缘栅极型功率管 IGBT器件, 或者可控继电器。
11. 一种太阳能光发电系统控制方法, 其特征在于, 包括如下步骤:
接收太阳能电池阵列输出的多路电能, 对所述多路电能的特性进行检测; 根据检测得到的所述多路电能的特性, 根据所述特性对所述多路电能进行串联和 / 或并联动态组合调整, 输出一路或多路电能。
12. 如权利要求 11所述的控制方法, 其特征在于, 所述根据所述特性对所述多 路电能进行串联和 /或并联动态组合调整, 输出一路或多路电能包括以下其中一种或几 种组合:
将性能相似的多路电能并联成一路输出; 或者, 关断发生故障的电能输出; 或者,
将多路电能串联成一路输出。
13. 如权利要求 11所述的控制方法, 其特征在于, 所述根据所述特性对所述多 路电能进行串联和 /或并联动态组合调整, 输出一路或多路电能包括:
通过切换开关组件中的多个开关单元对所述多路电能进行串联和 /或并联动态组合 调整,所述开关组件中的多个开关单元用于将太阳能电池阵列的输出进行串并联连接组 合。
14. 如权利要求 13所述的控制方法, 其特征在于:
所述开关单元为金属氧化物半导体 M0S管, 或者绝缘栅极型功率管 IGBT器件, 或者 可控继电器。
PCT/CN2010/079748 2010-04-01 2010-12-14 太阳能光发电系统、控制装置及控制方法 WO2011120311A1 (zh)

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