method of reactive power regulation in a wind farm connected to an electrical grid, method of reacti

专利摘要:
method of regulation of reactive power in a wind farm and in a wind turbine, and wind farm. the present invention relates to a method of regulating reactive power in a wind turbine (100,200, n00), which comprises at least one local reactive power control system (120,220, n20, x20) adapted to operate in a central control mode and local control mode, a method of regulating reactive power in a wind farm connected to an electrical network (10) and a wind farm.
公开号:BR112013002727B1
申请号:R112013002727
申请日:2010-08-02
公开日:2020-01-14
发明作者:Montserrat Mata Dumenjó；Jordi Carulla Piera；Oriol GOMIS BELLMUNT
申请人:Ge Renewable Technologies Wind B.V.；
IPC主号:

专利说明:

“REACTIVE POWER REGULATION METHOD IN A WIND FARM CONNECTED TO AN ELECTRIC NETWORK, REACTIVE POWER REGULATION METHOD IN A WIND TURBINE AND WIND FARM CONNECTED TO AN ELECTRIC NETWORK”
Field of Invention [001] The present invention relates to a method for regulating reactive power in a wind farm, a method for regulating reactive power in a wind turbine and a wind farm.
Background to the Technique [002] With the increasing use of wind energy for electricity generation, network operators (TSO's or Transmission System Operators) have introduced stricter requirements for wind farm operators in relation to active power generation and reactive in support of the grid. For example, wind farm operators may not be required to always generate maximum available active power depending on wind conditions. Also, according to some network codes, wind farms must support the grid during a power outage. voltage and do not, for example, disconnect from the network.
[003] In this regard, it is known to vary the reactive power generated in a wind farm according to a grid voltage at a Common Coupling Point (PCC). It is also known to vary the active power generated in a wind farm according to a measured grid frequency.
[004] EP 1.850.002 discloses a wind farm comprising a number of fixed speed wind turbines and a number of variable speed wind turbines. The variable speed wind turbines are adapted to equalize an output of the wind farm, compensating for a variable output of the fixed speed wind turbines. These variable speed wind turbines can be independent or a
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2/24 central management can be provided to send control commands to each of the variable speed wind turbines.
[005] US 7,531,911 discloses a method of reactive power regulation on a wind farm in which a measured reactive power output from the wind farm is compared to a reactive power adjustment point; based on the difference between them, a reactive power command is generated. The reactive power commands for each of the wind turbines are determined as a percentage of a maximum instantaneous reactive power capacity for each of the turbines.
[006] US 2008/0073912 discloses a wind farm that includes at least two wind turbines from a master park configured for power factor control, to send global power coefficient signals to lower wind turbine level regulators.
[007] In general, control systems of the prior art are known, which are based either on a centralized control or on a decentralized control. An advantage of a centralized control approach can generally be that the control is stable. However, a disadvantage of centralized control may be that such control is not always able to react in a way that is sufficiently fast to network anomalies. An advantage of decentralized control may be that it is quicker to react to network anomalies, but a disadvantage may be that the control may be unstable. Thus, there is still a need for power control on a wind farm that can combine stable control with the ability to react quickly to grid anomalies.
[008] The present invention is intended to partially or completely fill this need. Other advantages
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3/24 will become evident from the description that follows.
Description of the Invention [009] In a first embodiment, the present invention provides a method of regulating reactive power in a wind farm connected to an electrical network, the wind farm comprising a plurality of wind turbines from a central reactive power control system , in which at least a first portion of the plurality of wind turbines comprises a local reactive power control system adapted to work in a central control mode, and a local control mode, in which the central reactive power control system sends commands indicative of local reactive power demands for local reactive power control systems according to at least one variable measured from the network; and in which in a central control mode, a local reactive power control system operates a wind turbine to generate reactive power in accordance with said commands; and in a local control mode, a local reactive power control system determines an amount of reactive power to be generated and controls a wind turbine to generate said amount of reactive power.
[0010] In accordance with this embodiment of the invention, a combination of centralized control and decentralized control is provided combining the advantages of both approaches.
[0011] In some embodiments, the local reactive power control system can switch from central control mode to local control mode when a measured local variable passes a local limit value for the wind turbine. An exceptional grid condition will generally be translated into an exceptional grid condition within the wind farm. One aspect of these achievements is that a local control system does not have to wait for a central control system to detect normality and translate this abnormality into control signals. Instead, a control system
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Local 4/24 is able to measure the abnormality and respond quickly. Optionally, switching over to local control is only done if the measured local variable passes a local limit value for at least a predetermined period of time. Preferably, the local limit values for each wind turbine are determined substantially in such a way that under normal grid conditions, the wind farm operates in central control mode and that in, or under grid conditions close to exceptional, the wind farm operates in the local control mode. One aspect of these achievements is that under normal network conditions, more stable centralized control can be used, while in or near exceptional network conditions, a faster response with local control is available. According to these achievements, under exceptional network conditions all wind turbines with local reactive power control systems can be in local control mode, or only part of them. A TSO can determine what normal network conditions are. Any network condition that is not considered normal can be considered exceptional. An example of an exceptional grid condition may be, for example, a grid voltage outside predefined limit values.
[0012] In some embodiments, the local limit values for each wind turbine are voltages, and said measured local variables are local voltages. In some of these projects, local limit values for each wind turbine comprise a minimum voltage and a maximum voltage.
[0013] In some embodiments, local limit values may be constant. In alternative embodiments, local limit values can be determined according to at least one measured variable.
[0014] In some embodiments, the amount of reactive power generated in a local control mode can be either the maximum or minimum amount of reactive power that a wind turbine can actually generate. In some embodiments, local control systems can determine the
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5/24 maximum and minimum amount of reactive power that a wind turbine can generate according to the operating conditions of the wind farm and / or each wind turbine. Conditions that can be taken into account include, for example, thermal conditions of generator and / or converter components.
[0015] Alternatively, local control systems can use predefined maximum and minimum (which must be within the actual operational limits of the generator and / or converter).
[0016] In some embodiments, a local reactive power control system can switch from central control mode to local control mode when an absolute value of a rate of change of a measured local variable (for example, a local voltage) exceeds a local limit rate. In these embodiments, the local control mode can be activated when a rate of change (either positive or negative) passes a limit rate. Optionally, local limit rates can be constant. Local limit rates can also be determined according to at least one measured variable.
[0017] In some embodiments, local reactive control systems switch from central control mode to local control mode when a sudden change in a measured local variable exceeds proportions of local limits. Optionally, said local limit proportions comprise an absolute local limit difference. In these embodiments, the switching is not necessarily determined by an instantaneous value of a rate of change of a voltage, but, instead, by a jump of a certain dimension over a certain time. In these achievements, the rate of change is thus indirectly taken into account.
[0018] In some embodiments, when a local control system switches from a central control mode to a local control mode in response to a rate of change of a measured local variable that exceeds
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6/24 a local limit rate, in the local control mode the amount of reactive power to be generated can be determined according to the recorded rate of change and / or operating conditions of the wind farm, and / or operating conditions of the wind turbine.
[0019] In some embodiments, when a local control system switches from a central control mode to a local control mode in response to a sudden change in a local variable measured that exceeds local limit proportions, in local control mode the amount reactive power to be generated can be determined according to the sudden change recorded and / or operating conditions of the wind farm, and / or operating conditions of the wind turbine.
[0020] In some embodiments, the local limit values and / or limit rates and / or local limit proportions for a sudden change, can be calculated periodically, either by a central control system or by means of local control systems, or it can be provided, for example, through a pre-calculated lookup table. The local limit values, and / or local limit rates, and / or local limit proportions, can also be determined according to an algorithm obtained with an artificial neural network.
[0021] In some embodiments, the local limit values, and / or local limit rates, and / or local limit proportions, for a sudden change of a variable, can be determined by means of the central reactive power control system and provided for each of the local reactive power control systems. In other embodiments, local limit values, and / or local limit rates, and / or local limit ratios, can be determined using each of the local reactive power control systems.
[0022] In some embodiments, a local reactive power control system may switch from local control mode to central control mode after a predetermined amount of time to operate
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7/24 in local control mode has elapsed. In other embodiments, a local reactive power control system can switch from the local control mode to the central control mode according to the operating conditions of the wind farm, and / or power grid, and / or wind turbines.
[0023] In some embodiments, in the central control mode, a demand for central reactive power can be determined in response to a measured mains voltage. Optionally, commands indicative of local reactive power demands can be determined by distributing the central reactive power command among the plurality of wind turbines, such that each local power control command represents the same percentage of the maximum available local reactive power of each wind turbine. In alternative embodiments, different distribution algorithms, or distribution keys, can be used.
[0024] In another embodiment, the invention provides a method of regulating reactive power in a wind turbine, which comprises receiving commands indicative of a demand for local reactive power from a central reactive power control system; obtain a maximum and minimum local tension; obtain an instantaneous value of the local voltage from a measuring device, and compare that instantaneous value for the local voltage with the limit values; and if the local voltage is greater than the maximum local voltage, send control commands to at least one component wind turbine to generate the maximum available inductive reactive power; and if the local voltage is less than the minimum local voltage, send control commands to at least one component wind turbine to generate the maximum available capacitive power. In this embodiment, a method of controlling a wind turbine is provided, which is able to quickly and steadily provide support for a grid.
[0025] In some embodiments, the power regulation method
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8/24 reactive in a wind turbine can also comprise obtaining an absolute rate of change of a local voltage, determining a rate of change of a local voltage based on the values obtained from the local voltage from the measuring device and, if the determined absolute rate of voltage change is greater than the absolute rate of change limit, locally determine the amount of reactive power to be generated and send control commands to at least one component wind turbine to generate said amount of reactive power. In these embodiments, wind turbines are not only quick to react to a particularly high or particularly low voltage in the grid, voltage changes are also taken into account.
[0026] Optionally, obtaining an absolute rate of change limit for a local voltage comprises receiving the absolute rate of change limit from the central reactive power control system. Another option is that obtaining an absolute rate of change limit for a local voltage comprises calculating the absolute rate of change limit.
[0027] In alternative embodiments, the method also comprises obtaining local limit proportions for a sudden difference in voltage, determining a sudden difference in voltage based on the values obtained from the local values from the measuring device and, if the sudden difference in voltage exceeds the local limit proportions, locally determine the amount of reactive power to be generated, and send control commands to at least one component wind turbine to generate this rise in reactive power. In these projects, wind turbines are able to react quickly to voltage jumps, both positive and negative, in the network.
[0028] In another embodiment, the invention also provides a computer program product, which comprises program instructions for making a computer system perform a method of regulating reactive power in a wind turbine, substantially as described here
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9/24 previously. Said computer program can be configured on a storage device, for example, in a recording medium or a computer memory, or in a read-only memory, or loaded into a carrier signal to be, for example, downloaded from a computer. or sent by email (for example, on a carrier, electrical or optical signal).
[0029] In yet another embodiment, the invention provides a wind farm connected to an electrical grid, and comprises a plurality of wind turbines, in which at least a portion of the plurality of wind turbines comprises a local reactive power control system , capable of controlling the reactive power that a wind turbine generates, the wind farm still comprising a central reactive power control system capable of determining commands indicative of local reactive power demands for each of the local reactive power control systems, in response to at least one measured variable of the network, and send commands to the local reactive power control systems, and the local reactive power control systems being adapted to work in a central control mode and a local control mode, in which in a central control mode the local reactive power control system controls a wind turbine to generate reactive power according to a command received from the central reactive power control system, and in which, in a local control mode, the local reactive power control system determines an amount of reactive power to be generated through the corresponding wind turbine and controls the wind turbine to generate said amount of reactive power.
[0030] In some embodiments, the local reactive power controls are adapted to control a converter and / or a step system.
[0031] In some embodiments, the wind farm may comprise an additional reactive power compensation device such as, for example, capacitor banks and / or inductive banks, and reactive power control
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Central 10/24 can be adapted to control these reactive power compensation devices. In these projects, the wind farm comprises more possibilities to control the reactive power generated.
[0032] In yet another embodiment, the invention provides a method of regulating reactive power in a wind turbine that comprises receiving commands indicative of a local reactive power control system; obtain an absolute rate of change of local voltage limit; obtain instantaneous values of the local voltage from a measuring device; determine a rate of change of a local voltage based on the values obtained from the local voltage from the measuring device and, if the rate of change of absolute voltage is less than the limit rate of change, send control commands for at least a component wind turbine to generate reactive power according to the commands received from the central reactive power control system; and if the rate of change of absolute voltage determined is greater than the limit rate of change, locally determine the amount of reactive power to be generated and send control commands to at least one component wind turbine to generate said amount of reactive power.
[0033] In yet another embodiment, the invention provides a method of regulating reactive power in a wind turbine that comprises receiving commands indicative of a local reactive power control system; obtain local limit proportions for a sudden change in local voltage, obtain instantaneous values of the local voltage from a measuring device; determine a sudden difference in voltage based on the values obtained from the local voltage from the measuring device and, if the sudden change in voltage is less than local limit proportions, send control commands to at least one component wind turbine to generate power reactive according to the commands received from the central reactive power control system and, if the sudden difference in voltage exceeds the local limit proportions,
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11/24 locally determine the amount of reactive power to be generated, and send control commands to at least one component wind turbine, to generate said amount of reactive power.
Brief Description of the Drawings [0034] Particular embodiments of the present invention will be described in the following, by way of non-limiting examples, with reference to the accompanying drawings, in which:
figure 1a schematically illustrates a first construction of a wind farm in accordance with the present invention;
figure 1b schematically illustrates lines of communication in said first embodiment;
figures 2a and 2b illustrate a central reactive power control according to some embodiments of the present invention; and
figures 3a and 3b illustrate realizations of control methods according to the present invention, in a central control system and a local control system, respectively.
Description of Realizations of the Invention [0035] Throughout the description reference is made to a maximum or minimum amount of reactive power, a positive or negative amount of reactive power, as well as an increase or decrease in reactive power. Within the scope of this description, a positive reactive power is considered to be capacitive reactive power; a maximum amount of reactive power is thus considered to be the maximum possible capacitive reactive power, and an increase in reactive power is thus considered to be an increase in capacitive power (or a decrease in inductive power). A negative reactive power is considered to be inductive reactive power; a minimum amount of reactive power is thus considered to be the maximum possible inductive reactive power, and a decrease in reactive power is thus
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12/24 considered to be an increase in inductive power (or a decrease in capacitive power).
[0036] Figure 1a schematically illustrates a wind farm comprising n 100, 200 ... n00 wind turbines. At least a portion of the n wind turbines comprises a local reactive power control system 120, 220, ... n20. Reactive local control systems can be incorporated into a larger generic local control system, or they can be a dedicated isolated control system. Each of the wind turbines comprises a 110, 210, n10 generator.
[0037] The wind farm still comprises a central reactive power control system 20. Also the central reactive power control system 29 can be part of a general central wind farm control system or it can be a dedicated isolated control system .
[0038] The wind farm is connected to an electrical grid 10 at a Common Coupling Point (PCC). Each of the wind turbine generators can be connected to the medium voltage wind farm network 40 via a suitable transformer 130, 230, ... n30. The medium voltage wind farm network 40 can be connected to the high voltage power grid through a suitable transformer 30.
[0039] Illustrated schematically with dotted lines, there are lines of communication between the central reactive power control system 20 with each of the local reactive power control systems 120, 220, ... n20. Data can thus be exchanged and the central control system 20 can send commands to the local control systems. Each of the local control systems is, in addition, able to communicate with its corresponding generator and converter, if present. Data from the generator and converter (currents, voltages) can thus be collected by the local control system and the local control system can provide commands to control the turbine
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13/24 wind power and at least some of its components.
[0040] Figure 1b illustrates, in a schematic way, lines of communication in said first realization. A TSO 5 can communicate the requirements for a wind farm 20 central reactive power control system. The central control system can, according to one or more measurements 15, send instructions to a local x20 reactive power control system. Based on these instructions and based on one or more x15 measurements, in this embodiment, the x20 local control system can control an x22 converter control system and an x24 step control system. The x22 converter control system and the x24 step control system are able to communicate their operation to the x20 local control system. Controlling both the pitch and the converter. the local control system may be able to control, for example, the active power of the wind turbine, the speed of the wind turbine, the generation of reactive power, frequency control, voltage control, and LFRT (Line Fault Ride-Through behavior) ).
[0041] A measurement 15, on which the central control 20 can base its instructions, can be a line voltage at or near the PCC. X15 measurements that can be taken into account by local controls 120, 220, x20, etc., can be local voltages.
[0042] According to embodiments of the invention, in response to a locally measured voltage, the control mode of one or more of the local reactive power control systems can be switched from a central control mode (in which instructions sent to the local control x20 are followed by the local control system) to a local control mode (in which the local control systems determine amounts of reactive power to be generated and control the wind turbines accordingly). In some embodiments and in some circumstances, the amounts of reactive power to be generated can be, for example, a minimum amount or a maximum amount
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14/24 reactive power.
[0043] Figure 2a illustrates one of the requirements that a TSO can provide to a wind farm operator. Within a certain range of grid voltages, the amount of reactive power that a wind farm operator may be asked to distribute can vary linearly according to one of the lines shown. Figure 2a shows an example of a 4950 kVAR wind farm and a 33 kV PCC voltage. The TSO may, depending on the circumstances, require a wind farm operator to distribute reactive power according to one of the straight lines a, b or c shown. More than such lines can be provided by a TSO. Alternatively, the corresponding values can be provided to the wind farm operator in the form of one or more tables that specify how much reactive power should be generated in response to varying grid conditions.
[0044] In general, each of the straight lines a, b and c can be described with the following equation:
HsfF - ~ 'k (Humid ~ Uref)
Equation 1 where QWF is a reference reactive power (reactive power to be generated by the wind farm), Humidida is a voltage measured at the PCC, llref is a reference voltage at the PCC that can be supplied by a TSO, Ub is a voltage ( or medium voltage or high voltage) and k is a constant. Both Ub and k can be provided by a TSO. Each of the lines a, b and c in figure 2a represents a line with a different constant k.
[0045] In practice, a TSO may require a certain slope for the straight line (a, b or c), usually in the form of a percentage g. THE
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Constant 15/24 k. however, it will depend on the reactive power capacity of the wind farm, and can be determined according to:
g
Equation 2 in which Qmax is the maximum reactive power capacity of the wind farm.
[0046] When the grid voltage is outside the limits shown in figure 2a, a wind farm operator may be asked to generate maximum capacitive available reactive power, or to generate minimum inductive available reactive power. In the particular embodiment shown, when the grid voltage is within limits (and other anomalies are absent), the grid can be said to be in normal condition. When the mains voltage is out of limits, the mains can be said and started under exceptional conditions. The definition of normal network conditions and exceptional network conditions may depend on the network and the TSO.
[0047] Figure 2b further illustrates a possible central control method according to some embodiments of the invention. Once a required amount of reactive power Q * WF has been determined in accordance with TSO requirements, this Q * WF is compared to the amount of reactive power actually generated at that time QWF. The difference between these two values (the error) can be introduced for a PID controller that generates a central reactive power control command Qref.
[0048] For different embodiments of the invention, the values of the constants for the proportional, integral and derivative components may vary and for some embodiments, some constants may be equal to zero. A PID control is, however, merely one of the possible control methods
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16/24 that can be used in a central reactive power control system in realizations of the invention.
[0049] A compensation factor q _C om can be added to compensate the wind farm capacitance. In some embodiments of the invention a compensation factor q _C om can be determined according to
Equation 3 in which Fi indicates for each wind turbine whether a particular wind turbine is operative or not (if operative, then F = 1, if not operative, then F = 0), Xcci is the transformer reactance of a particular wind turbine, li is the current in the transformer in a particular wind turbine, Xccwf is the reactance of the wind farm transformer and Itrwf is the current in the wind farm transformer. If the wind farm comprises capacitive banks or other reactive power compensation devices such as, for example, induction banks, and if they are active, they can also be taken into account in the compensation factor.
[0050] According to figure 2b, the compensation factor Qcom can be added to the demand for central reactive power control Qref. The result is a demand for compensated central reactive power control Q * ref.
[0051] This demand for central reactive power control Qref can be introduced for a dispatch function that determines the quantities of reactive power Q100, Q200 etc., which can be requested from each of the local wind turbine control systems. According to a
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17/24 realization, the demand for central control Q * and f can simply be divided equally among all wind turbines.
[0052] According to other realizations, the demand for central control can be divided in such a way that substantially the same percentage of available reactive power is generated in each of the wind turbines. The commands sent to each of the local control systems can be determined, for example, according to the following equations:
Equation 4
Q * ref is the demand for compensated central reactive power control and indicates, for each wind turbine, whether it is within its operational limits or not (E = 1 within operational limits; E = 0 if the wind turbine is in its operational limits, the theoretical turbines thus generating their maximum or minimum reactive power), Qimax is the maximum available reactive power for each of the wind turbines, and the Qnec result is the amount of reactive power that must be generated by the wind turbines in central control;
Equation 5 in which Qmaxtotai is the maximum available amount of reactive power for wind turbines that are in central control mode and Fi still indicates for each wind turbine whether a particular wind turbine is operational or not (F = 1 if operative and F = 0 if not operative); and
Q, _ ______QftfC______
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18/24
Equation 6 in which α is a factor that indicates how much of the available reactive power each wind turbine could generate. The central control system can send factor α to each of the local controls or it can send signals of corresponding quantities to each of the wind turbines.
[0053] Regardless of the amounts of reactive power to be produced by each wind turbine that has a local control system, other information can also be sent to each of the local control systems. In some embodiments, the central control system may send dynamic non-constant limit values to the local control systems indicating when the local control system should switch to a local control mode. Local control systems can thus determine themselves to switch to a local control mode and do not need to wait for a particular command to do this. The limit values can be determined substantially in such a way that under normal grid conditions the wind farm operates in central control mode and that under or close to exceptional grid conditions, the wind farm operates in local control mode. Under exceptional network conditions, local control may thus be able to react more quickly in response to locally measured parameters. For example, limit values sent to local control systems can be determined according to:
Sup lint. - (I + g 0.0 1 + Su _sraf + Y 4- -h _,. ) * U, „
Lim min _; = (1 - g · 0.01 + + Λ,) * U *
Equation 7 where g is the previously defined slope prescribed by TSO, Autraf is the normalized voltage drop for the wind farm transformer, Σ Auiine is the sum of the normalized voltage drops for the connection lines
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19/24 electrical, Autrafi is the normalized voltage drop for the wind turbine transformer i, Ubt is the low voltage on the wind farm side of the transformer, and hi is an adjustment parameter for the wind turbine i.
[0054] In this embodiment, the setting parameter h for wind turbine i can be determined according to:
= ^Aíf w + Σ + ^{Ál {} '^ + M
Equation 8 where Upcc is the normalized voltage in the PCC and uiocai is the normalized local voltage in a wind turbine.
[0055] The standard voltage drops for each of the separate components can be calculated according to
Δ »= T (/ . cos (p + À, sin (p) _t
Equation 9a in which I is the current that circulates through a particular part of the wind farm (for example, a cable section, or transformer), R is the resistance of the particular part of the wind farm, X is the reactance of a particular part of the wind farm and φ is the power factor angle.
Alternatively, normalized voltage drops can be calculated according to
P R + Q X
Equation 9b in which, for example, for the wind farm transformer:
P is the active power of the wind farm, Q is the reactive power of the wind farm, R is the transformer resistance and X is the transformer reactance and U is the nominal voltage in the PCC. Voltage drops for each
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20/24 stretch of electric line and for each wind turbine transformer can be determined in a similar way, using the appropriate resistance, reactance, active power and reactive power.
[0056] In the manner described, maximums and minimums for local voltages can be sent to the local control systems of wind turbines. When a local voltage for a particular wind turbine reaches or exceeds one of the limit values, that particular wind turbine can switch to a local control mode. It should be noted that other wind turbines may still be in a central control mode, and may continue to receive and follow orders from the central control system. Wind turbines that are in local control mode can deliver predetermined amounts of reactive power which can, for example, be the maximum or minimum possible reactive power capacity.
[0057] Within the scope of the invention, the method of calculating the limit values through the central control system can be varied. For example, in equation 7, factor 1 + 0.01 g can be limited to a maximum of 1.05 and factor one - 0.01g can be limited to a minimum of 0.95. Other variations are also possible. Also, in some embodiments of the invention, local limit values can be calculated using local control systems. In other embodiments, local limit values can be constant and can be determined, for example, during a trial or test phase of a wind farm.
[0058] In other embodiments of the invention, a high rate of change of a local voltage can prompt a local control system to switch from a central control mode to a local control mode. In another example, a sudden change in voltage of certain proportions (for example, a predetermined voltage difference is achieved in a very short period of time) can prompt such a switch. Limit rates
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21/24 of change and / or the limit proportions of sudden changes can be determined by the local control system itself, they can be distributed by the central reactive power control system or they can be constant.
[0059] Figure 3a illustrates a control method in a central control mode in accordance with an embodiment of the present invention. In step 1000 the central control method is started, and initial parameter values are determined, for example, reactance for the wind farm components. Steps 1001, 1002 comprise data collection from, respectively, the PCC and local control systems. Data that can be collected from the PCC may include, but is not limited to, voltage at the PCC, current at the PCC, frequency of the grid, active power generated by the wind farm, and reactive power generated by the wind farm. Data that can be collected from one or more of the wind turbines in the park may include, but are not limited to, active power generated, reactive power generated, the state of the wind turbine (operational or not; within operational limits or not; in local control mode, or in central control mode, the maximum available reactive power capacity (capacitive), the minimum reactive power capacity (inductive), local voltage, current and frequency.
[0060] The maximum and minimum available reactive power may vary with local variable voltage. The values for the maximum and minimum available reactive power can be calculated using the local control systems sent to the central reactive power control system.
[0061] Step 1003 comprises the calculation of the central reactive power control command and the calculation of instructions to be sent to local control systems. This calculation can be, for example, according to equations 1 and 2. If the mains voltage is outside pre-defined limits (see, for example, figure 2a) the central reactive power control command can be the maximum or minimum reactive power available for the wind farm.
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22/24 [0062] Instructions sent to a local control system may include, but are not limited to, local reactive power commands (which may, in some embodiments, be calculated according to equations 3 to 6) limit values local (which can, in some embodiments, be calculated according to equations 7 to 9) and local limit rates.
[0063] Step 1004 comprises sending commands indicating the reactive power to be generated locally to local control systems. The implementation of commands by local control systems and varying network conditions, can lead to new values for one or more variables, so that steps 1001, 1002 and 1003 can be repeated continuously.
[0064] Figure 3b illustrates a control method in a local control system according to some realizations of the present invention. In a 2000 method step, the control method is started. In a 2001 stage, certain variables can be measured such as, for example, local voltage, current, active and reactive power. In a 2002 step, the values of these variables can be sent to a central control system. Other parameters / variables that can be sent to a central control system may include, for example, the status of the wind turbine (operational or not), the operating status of the wind turbine (within operational limits or not), the mode of control (central control mode or local control mode).
[0065] In a 2003 step, control signals for, for example, the converter can be calculated and in a 2004 step these control signals can be sent to the converter. As can be seen in figure 3b, the separate method steps are not necessarily sequential, but instead take place continuously and simultaneously. They can each have their own operating speeds and frequencies: in some embodiments, measuring certain variables can take place, for example, every 0.01s,
Petition 870190088671, of 09/09/2019, p. 36/83
23/24 while sending data to the central control system can take place, for example, every 0.3 seconds.
[0066] Stage 2010 comprises receiving local limit values from the central control system and comparing them with instantaneous local variables. The comparison can lead to a determination of within limits in step 2011, or out of limits in step 2012. If the determination out of limits is made, the local control system will switch to a local control mode.
[0067] Once the local reactive power control system has switched to local control mode, the local control system will determine the amount of reactive power to be generated, despite commands received from a central control system . In some embodiments, the central control systems may switch back to a central control mode after a predetermined amount of time. The amount of time before returning to a central control mode can be determined according, for example, with the slope of the reactive power line to the voltage prescribed by a TSO. The amount of time before returning to a central control mode can be constant, can be calculated by the central control system, or can be calculated by a local control system. The amount of time before returning to central control mode may, in certain embodiments, also depend, for example, on the cause of switching from central control mode to local control mode (eg voltage value off of limits, rate of change of voltage outside limits, or sudden change in voltage outside limit proportions.When switching back to a central control mode, if the determination outside limits is made again, the local control mode will be resumed .
[0068] In other embodiments the local control will switch back to a central control mode when one or more measured variables meet a predefined requirement. Also combinations of a return
Petition 870190088671, of 09/09/2019, p. 37/83
Time-dependent and variable-dependent 24/24 for a central control mode can be used.
[0069] The method of reactive power control for the wind farm can also be adapted to include algorithms for removing certain wind turbines from operation if, for example, the wind turbine does not follow the commands of the central control system or, for example, whether a particular wind turbine remains in operation (or switching to) local control mode, or whether the wind farm is unable to distribute the prescribed reactive power values, or, for example, if switching failures are noted, etc.
[0070] Furthermore, in realizations of the invention, wind turbines within the same wind farm can comprise different local reactive power control systems. For example, some local reactive power control systems can be adapted to switch to a local control mode only in response to an instantaneous voltage, while other local reactive power control systems switch only in response to or also in response, At a rate of change in voltage, yet other local reactive power control systems can be adapted to switch only in response to, or also in response to, voltage jumps of specified proportions.
[0071] Although this invention has been disclosed in the context of certain preferred embodiments and examples, it will be understood by those skilled in the art that the present invention extends beyond the specifically disclosed embodiments, to other alternative embodiments and / or uses of the invention, and obvious changes to its equivalents. Thus, it is projected that the scope of the present invention disclosed herein should not be limited by the particular disclosed accomplishments described above, but should be determined only by a fine reading of the claims that follow.

权利要求:
Claims (14)
[1]
Claims
1. REACTIVE POWER REGULATION METHOD
IN A WIND FARM CONNECTED TO AN ELECTRIC NETWORK (10), the wind farm comprising a plurality of wind turbines (100, 200 ... n00) and a central reactive power control system (20), in which at least one first portion of the plurality of wind turbines (100, 200 ... n00) comprises a local reactive power control system (120, 220 ... n20, x20) characterized by the fact that:
the local reactive power control system (120, 220 ... n20, x20) is adapted to switch between a central control mode and a local control mode, and to work in a central control mode or a control mode local, in which the central reactive power control system (20) sends commands indicative of the local reactive power demands to the local reactive power control systems (120, 220 ... n20, x20) according to, at least , a measured variable (15) of the network (10), in which in a central control mode, a local reactive power control system (120, 220 ... n20, x20) operates a wind turbine (100,
200 ... n00) to generate reactive power according to commands indicative of local reactive energy demands received from the central reactive power control system (20), and in which in a local control mode, a control system for local reactive power (120, 220 ... n20, x20) receives commands indicative of local reactive energy demands from the central reactive power control system (20), and determines an amount of reactive power to be generated and controls a wind turbine (100, 200 ... n00) to generate amount of reactive power, and in which a local reactive power control system (120, 220 ... n20)
Petition 870190088671, of 09/09/2019, p. 39/83
[2]
2/7 switches from central control mode to local control mode when a measured local variable (x15) passes a local limit value to the wind turbine (100, 200 ... n00) for at least a predetermined period of time, and where the local limit values for each wind turbine (100, 200 ... n00) are determined in such a way that under normal grid conditions the wind farm operates in central control mode, and that under exceptional grid conditions the wind farm operates in local control mode, and in local control mode, the amount of reactive power to be generated is the maximum or minimum amount of reactive power that a wind turbine (100, 200 ... n00) generates.
2. METHOD, according to claim 1, characterized by the fact that the local limit values for each wind turbine (100, 200, n00) are voltages and said measured local variables (x15) are local voltages and, where the values Local limits for each wind turbine (100, 200 ... n00) comprise a minimum voltage and a maximum voltage.
[3]
3. METHOD, according to any one of claims 1 to 2, characterized by the fact that the local limit values are constant or are determined according to at least one measured variable (x15).
[4]
4. METHOD according to any one of claims 1 to 3, characterized by the fact that the maximum and minimum amounts of reactive power that a wind turbine (100, 200 ... n00) generates are determined according to the operating conditions of the wind farm and / or wind turbine (100, 200 ... n00).
[5]
5. METHOD according to any one of claims 1 to 4, characterized by the fact that a local reactive power control system (120, 220 ... n20, x20) switches from the control mode
Petition 870190088671, of 09/09/2019, p. 40/83
3/7 central to local control mode when an absolute value of a rate of change of a measured local variable (x15) exceeds a local limit rate or, when a sudden change of a measured local variable (x15) exceeds proportions of local limits , in which the local limit proportions comprise an absolute local difference.
[6]
6. METHOD, according to claim 5, characterized by the fact that the measured local variable (x15) is a local voltage.
[7]
7. METHOD according to any one of claims 5 to 6, characterized by the fact that local limit values and / or local limit rates and / or local limit ratios are determined using a lookup table or are calculated periodically.
[8]
8. METHOD, according to any one of claims 1 to 7, characterized by the fact that the local limit values and / or the local limit rates and / or the local limit proportions are determined by means of the central reactive power control system ( 20) and provided for each of the local reactive power control systems (120, 220, n20, x20).
[9]
9. METHOD according to any of claims 1 to 9, characterized by the fact that the local reactive power control systems (120, 220 ... n20, x20) switch from the local control mode to the central control mode after a predetermined amount of time has elapsed operating in local control mode and, where the predetermined amount of time is calculated by the local reactive power control system (120, 220 ... n20, x20) and, where the predetermined amount of time depends on the cause of switching from central control mode to local control mode.
[10]
10. METHOD according to any of claims 1
Petition 870190088671, of 09/09/2019, p. 41/83
4/7 to 9, characterized by the fact that the local reactive power control systems (120, 220 ... n20, x20) switch from the local control mode to the central control mode according to the operating conditions of the wind farm and / or electric grid (10) and / or wind turbines (100, 200..n00).
[11]
11. REACTIVE POWER REGULATION METHOD IN A WIND TURBINE (100, 200 ... n00), which comprises receiving commands indicative of a local reactive power demand (Q * WF) from a central reactive power control system (20);
obtain a maximum local voltage and a minimum local voltage;
obtain an instantaneous value of the local voltage from a measuring device and compare the instantaneous values for the local voltage with the limit values, the method being characterized by the fact that if the local voltage is between the maximum and the minimum local voltage, work in a central control mode by sending control commands to at least one wind turbine component to generate the demand for local reactive power received through the central reactive power control system (20), and if the local voltage is greater than the voltage maximum local for at least a predetermined period of time, work in a local control mode by sending control commands to at least one wind turbine component to generate the maximum available inductive reactive power regardless of the local reactive power demand received through the central reactive power control system (20), and if the local voltage is less than the minimum local voltage during before at least a predetermined period of time, work in a local control mode by sending control commands to at least one wind turbine component to generate the available capacitive power
Petition 870190088671, of 09/09/2019, p. 42/83
5/7 maximum regardless of the local reactive power demand received through the central reactive power control system (20).
[12]
12. METHOD, according to claim 11 characterized by the fact that it additionally comprises the step of obtaining an absolute rate of change of a local voltage, determining a rate of change of a local voltage based on the values obtained from the local voltage from the measuring device, and if the rate of change of absolute determined voltage is greater than the absolute rate of change limit, locally determine the amount of reactive power to be generated and send control commands to at least one component wind turbine to generate this amount of reactive power.
[13]
13. METHOD according to any one of claims 11 to 12, characterized by the fact that if the absolute determined voltage rate of change is less than the absolute rate of change limit and the local voltage is between the maximum local voltage and minimally, send control commands to at least one wind turbine component to generate reactive power according to the commands received from the central reactive power control system (20).
[14]
14. WIND FARM CONNECTED TO AN ELECTRICAL NETWORK (10) and comprising a plurality of wind turbines (100,
200 ... n00), in which at least a portion of the plurality of wind turbines (100,
200 ... n00) comprises a local reactive power control system (120,
220 ... n20, x20) capable of controlling the reactive power (QWF) that a wind turbine generates, the wind farm still comprising a central reactive power control system (20) capable of determining commands indicative of local reactive power demands (Q100,
Petition 870190088671, of 09/09/2019, p. 43/83
6/7
Q200, Q300, Q400, Qnoo) for each of the local reactive power control systems (120, 220 ... n20, x20) in response to at least one measured variable of the network, and send the commands to the control systems local reactive power (120, 220 ... n20, x20), characterized by the fact that:
the local reactive power control systems (120, 220, n20, x20) are adapted to switch between a central control mode and a local control mode and work in both central control mode and local control mode, in which in a central control mode the local reactive power control system (20) controls a wind turbine (100, 200 ... n00) to generate reactive power according to a command received from the reactive power control system (120, 220 ... n20, x20) and in which, in a local control mode, the local reactive power control system (120, 220 ... n20, x20) determines an amount of reactive power to be generated by the corresponding wind turbine (100, 200, n00) independent of the commands received through a central control system and controls the wind turbine to generate said amount of reactive power, in which a local reactive power control system (120, 220 ... n20, x20) is conf configured to switch between central control mode and local control mode when a measured local variable passes a local limit value to the wind turbine (100, 200 ... n00) for at least a predetermined period of time, and where the local limit values for each wind turbine (100, 200. n00) are determined in such a way that under normal grid conditions, the wind farm operates in central control mode and that under exceptional grid conditions, the wind farm operates in local control mode, and
Petition 870190088671, of 09/09/2019, p. 44/83
7/7 where in the local control mode, the amount of reactive power to be generated is the maximum or minimum amount of reactive power that a wind turbine (100, 200 ... n00) generates.

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法律状态:
2017-07-11| B25A| Requested transfer of rights approved|Owner name: ALSTOM HYDRO ESPANA, S.L. (ES) |

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2017-07-25| B25A| Requested transfer of rights approved|Owner name: ALSTOM RENEWABLES ESPANA, S.L. (ES) |

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2017-08-08| B25D| Requested change of name of applicant approved|Owner name: ALSTOM RENEWABLES ESPANA, S.L. (ES) |

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2018-05-22| B25D| Requested change of name of applicant approved|Owner name: GENERAL ELECTRIC RENOVABLES ESPANA, S.L. (ES) |

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2018-06-12| B25A| Requested transfer of rights approved|Owner name: GE RENEWABLE TECHNOLOGIES (FR) |

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2018-07-03| B25A| Requested transfer of rights approved|Owner name: GE RENEWABLE TECHNOLOGIES WIND B.V. (NL) |

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2019-01-15| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

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2019-03-12| B06T| Formal requirements before examination [chapter 6.20 patent gazette]|

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2019-07-02| B07A| Technical examination (opinion): publication of technical examination (opinion) [chapter 7.1 patent gazette]|

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2019-11-12| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2020-01-14| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 02/08/2010, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

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申请号 | 申请日 | 专利标题

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PCT/EP2010/061233|WO2012016585A1|2010-08-02|2010-08-02|Reactive power regulation of a windpark|

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