Patent Application
20210066921
The present invention relates to a method for detecting the input channel configuration of a multi-channel inverter.
As is known, a multi-channel inverter comprises an input section and an output section adapted to receive DC electric power from a DC electric system and provide AC electric power to an AC electric system, respectively.
As an example, in photovoltaic installations, a multi-channel inverter may comprise the input section electrically connected with a photovoltaic panel or a photovoltaic string and the output section electrically connected with an electric power distribution grid.
In a multi-channel inverter, the above-mentioned input section includes a plurality of input channels, each of which is electrically connected with a corresponding power converter (e.g. a DC/DC power converter) and, in operation, with a corresponding DC electric power source.
In many applications, e.g. in photovoltaic plants, multi-channel inverters may have some input channels electrically connected in parallel with a same DC source and other input channels operating independently, i.e. singularly connected with a corresponding DC source.
For this reason, during the commissioning phase, normally, the control unit of a multi-channel inverter has to be properly configured to take into account the physical connection status of the input channels and ensure a proper operation of the inverter.
In currently available installations, the above-mentioned configuration operation entails the intervention of specialized personnel.
As an example, in some cases, an operator can carry out such a configuration operation by manually setting a dip switch of the control unit of the inverter.
As a further example, in other cases, an operator can provide the control unit with configuration information indicative of the input channel configuration of the inverter through a HMI (e.g. a touch display) or by downloading a suitable configuration file.
As it is easy to understand, the need for carrying out the above-mentioned configuration operations entails a remarkable increase of the commission time and costs to put the photovoltaic inverter in condition to operate.
Nowadays, there is a relevant market demand for having multi-channel inverters that can be installed on the field with lowered (virtually null) commissioning time and costs.
In the state of the art, it is therefore quite felt the need for solutions overcoming or mitigating the above-illustrated drawbacks of the state of the art.
The present invention intends to respond to this need by providing a method for detecting the input channel configuration of a multi-channel inverter, according to the following claim 1 and the related dependent claims.
In a general definition, the method, according to the invention, comprises the following steps:
Preferably, said step b) of controlling said power converters comprises activating the power converter corresponding to said reference input channel and deactivating or maintaining deactivated the power converters corresponding to said remaining input channels.
According to an aspect of the invention, said step d) of performing a comparison between the input voltages of said input channels comprises checking whether the input voltages of said remaining input channels behave as the input voltage of said reference input channel.
According to an aspect of the invention, said determination procedure comprises the following step:
According to an aspect of the invention, said determination procedure further comprises the following steps:
According to an aspect of the invention, said determination procedure comprises the following step:
According to an aspect of the invention, if the input voltages of one or more second remaining input channels, different from said first remaining input channels, do not decrease as the input voltage of said reference input channel said determination procedure comprises the following steps:
Preferably, the method, according to the invention, comprises the step f) of storing configuration information indicative of the configuration status determined for said input channels.
In a further aspect, the present invention relates to a multi-channel inverter, according to the following claim 9 and the related dependent claims.
Further features and advantages of the present invention will be apparent in the following description of non-limitative embodiments with reference to the figures in the accompanying drawings, in which:
Referring to the cited figures, the present invention relates to a method for detecting the input channel configuration of a multi-channel inverter 100.
The multi-channel inverter 100 is particularly adapted for use in photovoltaic installations and, in the following, it will be described with particular reference to these applications without intending to limit the scope of the invention. In fact, the multi-channels inverter 100 may be conveniently used in low-voltage installations of different types, such as those including batteries, capacitor banks, and the like, as DC electric power sources.
For the sake of clarity, it is specified that the term “low voltage” refers to operating voltages lower than 1 kV AC and 1.5 kV DC.
With particular reference to
The input section 110 comprises a plurality of input channels CH1, CH2, . . . , CHi−1, CHi, . . . , CHN−1, CHN, each of which is electrically connected with a DC electric power source S1, S2, . . . , Si−1, Si, . . . , SN−1, SN when the inverter 100 is installed on the field.
The DC sources S1, . . . , SN may include photovoltaic panels or strings, batteries, capacitor banks or other electric and/or electronic apparatuses providing DC electric power in output (e.g. photovoltaic panel optimizing apparatuses).
The inverter 100 may be operatively coupled to DC sources S1, . . . , SN of a same type (e.g. all including photovoltaic panels or strings) or of different types (e.g. including photovoltaic panels or strings and/or batteries and/or capacitor banks and/or other apparatuses as illustrated above).
The input section 110 comprises a plurality of power converters C1, C2, . . . , Ci−1, Ci, . . . , CN−1, CN, each of which may comprise, for example, one or more DC/DC converters.
Conveniently, each power converter C1, . . . , CN is electrically connected with a corresponding input channel CH1, . . . , CHN.
The inverter 100 further comprises an output section 120 intended, in operation, to be electrically connected with an AC electric system 300, preferably an electric power distribution grid, e.g. of single-phase or multi-phase type.
The output section 120 may comprise, for example, one or more further power converters, e.g. one or more AC/AC converters.
Conveniently, the inverter 100 may comprise a coupling section 130 to electrically connect the input section 110 and the output section 120.
The coupling section 130 may comprise, for example, one or more capacitor banks (DC-Link stage) electrically connected in parallel between the output terminals of the input section 110 and the input terminals of the output section 120.
Conveniently, the inverter 100 comprises control means 140 to control its functionalities, in particular the operation of the input and output sections 110, 120.
In an industrial implementation of the inverter 100, the control means 140 may comprise one or more control units arranged on-board the inverter.
Preferably, the control means 140 include data processing resources 160 to carry out their functionalities.
If industrially implemented in analog manner, the data processing resources 160 may comprise suitably arranged electronic circuits of analog type.
If industrially implemented in a digital manner, the data processing resources 160 may comprise one computerized units (e.g. DSPs or microprocessors) configured to execute sets of software instructions stored or storable in a medium.
As a further alternative, the data processing resources 160 may comprise integrated circuits or other electronic arrangements (e.g. FPGAs, SoC, and the like) capable of processing analog and/or digital signals.
Preferably, the control means 140 are configured to control the power converters C1, . . . , CN of the input section 110 operatively associated to the input channels CH1, . . . , CHN.
As an example, the control means 140 are conveniently configured to activate or deactivate the above-mentioned power converters and/or operate them according to given working functions.
It is important to put in clear evidence that the control means 140 can control the input currents I1, I2, . . . , Ii−1, Ii, . . . , IN−1, IN flowing along each input channel CH1, . . . , CHN by suitably controlling the corresponding power converter C1, . . . , CN.
Supposing that the inverter 100 is operatively coupled to photovoltaic sources S1, . . . , SN at the input channels CH1, . . . , CHN, when a generic input channel CHi of the inverter 100 is electrically connected with a photovoltaic source Si, the input voltage Vi of said input channel typically follows the operational characteristic curve of said photovoltaic source, an example of which is schematically shown in
As it is possible to observe, said operational characteristic curve has a monotone trend, which means that, in operation, a single voltage value at said input channel univocally corresponds to a given current value flowing along said input channel.
When no input current flows (Ii=0 a part from said leakage currents) along said generic input channel CHi, the photovoltaic source Si operates at the working point WP1. In this case, the input voltage Vi of the input channel CHi is Vi=VOC, where VOC is a no-load voltage value. When an input current Ii flows along said generic input channel CHi, the photovoltaic source Si operates at a different working point WP2. In this case, the input voltage Vi of the input channel CHi decreases and takes a value Vi=VA, where VA is a unique voltage value corresponding to the working point WP2.
In operation, the position of the working point WP2 (and therefore the corresponding voltage value VA) depends on the current value IA imposed by the power converter Ci operatively associated to the generic input channel CHi.
The value IA of the current flowing along the input channel CHi depends, in turn, on the kind of regulation, for example a MPPT (Maximum Power Point Tracking) regulation, constant power regulation, or the like, carried out by said power converter Ci.
Of course, the above considerations are valid mutatis mutandis for other types of above-mentioned DC electric power sources depending on their operational characteristic curves.
In order to control the above-mentioned power converters, the control means 140 may be configured to provide suitable control signals, control variables, reference currents, reference voltages, control flags and the like.
Preferably, the inverter 100 comprises sensing means 150 adapted to provide the control means 140 with detection signals M indicative of the input voltages V1, V2, . . . , Vi−1, Vi, . . . , VN−1, VN of the input channels CH1, . . . , CHN (more precisely at the input terminals of said input channels).
In general, the DC electric system 200 (e.g. the DC sources S1, . . . , SN thereof), the AC electric system 300 and most of the components of the input section 110 (e.g. the input channel channels CH1, . . . , CHN and the corresponding converters C1, . . . , CN thereof), of the output section 120 and, possibly, of the coupling section 130 as well as the sensing means 150 may be of known type and will not be here described in further details for the sake of brevity.
With particular reference to
In general terms, the method 1 is aimed at detecting the input channel configuration of the multi-channel inverter 100.
For the sake of clarity, it is specified that the locution “detecting an input channel configuration of the multi-channel inverter” means the detection of the physical connection arrangement of the input channels of said inverter with a DC electric source, in practice detecting whether the input channels of said inverter are electrically connected in parallel with a same DC source or are singularly connected with a corresponding DC source.
In the following, for the sake of brevity, an input channel singularly connected with a corresponding DC electric power source is defined as “independent input channel” whereas input channels electrically connected in parallel with a same DC electric power source are defined as “parallel input channels”.
The method 1 comprises a step a) of selecting a reference input channel (e.g. the input CH1) among the input channels CH1, . . . , CHN of the inverter 100.
In a practical implementation of the invention, the reference input channel CH1 may be selected in a group of available input channels according to a predefined sorting order or according to a random sorting order.
As it will better emerge from the following, such a group of available input channels initially include all the input channels of the inverter 100. However, said group of available input channels comprises only selected input channels of the inverter 100 (in particular those still having an undetermined configuration status), when the method 1 is recursively repeated.
Upon carrying out the above-illustrated step a), the method 1 comprises a step b) of controlling the power converters C1, . . . , CN to allow an input current I1 higher than a current threshold ITH to flow along the reference input channel CH1 and to allow input currents I2, . . . , IN lower than said current threshold to flow along one or more remaining input channels CH2, . . . , CHN different from the reference input channel CH1.
In a preferred embodiment of the invention, the above-mentioned step b) comprises activating the power converter C1 corresponding to the selected reference input channel CH1 and deactivating the power converters C2, . . . , CN corresponding to the remaining input channels CH2, . . . , CHN.
Such preferred embodiment of the invention corresponds to the case in which the current threshold ITH is set as ITH=0 A.
However, other embodiments of the invention may provide for activating all the power converters C1, . . . , CN and controlling these latter in such a way that, at a given check instant, the input current I1 flowing along the reference input channel CH1 is higher than the current threshold ITH whereas the input currents I2, . . . , IN flowing along the remaining input channels CH2, . . . , CHN is lower than said current threshold.
To this aim, for example, the power converters C1, . . . , CN may be controlled in such a way that, at a given check instant, an input current I1 having a higher growth rate is allowed to flow along the reference input channel CH1 and input currents I2, . . . , IN having lower grow rates are allowed to flow along the remaining input channels CH2, . . . , CHN.
According to other embodiments (not shown), both the above-mentioned solutions or additional equivalent solutions may be implemented.
Upon carrying out the above-illustrated step b), the method 1 comprises a step c) of acquiring detection data D indicative of the input voltages V1, . . . , VN of the input channels CH1, . . . , CHN of the inverter 100 (more precisely at the input terminals of said input channels).
In a practical implementation of the invention, the detection data D may be acquired by suitably processing the detection signals M received from the above-mentioned sensing means 150.
Upon carrying out the above-illustrated step c), the method 1 comprises a step d) of performing a comparison between the input voltage V1 of the reference channel CH1 and each of the input voltages V2, . . . , VN of the remaining input channels CH2, . . . , CHN based on the detection data D so acquired.
Preferably, the above-mentioned step d) comprises checking whether the input voltages V2, . . . , VN of the remaining input channels CH2, . . . , CHN behave (more particularly decrease) as the input voltage V1 of the reference input channel CH1.
In a practical implementation of the invention, at a given check instant, the voltage differences between each input voltage V2, . . . , VN of the remaining input channels CH2, . . . , CHN and the input voltage V1 of the reference channel CH1 may be calculated and compared with predefined threshold values to determine whether the compared input voltages behave in a similar manner or in a different manner.
As an example, the voltages V1, V2 of the input channels CH1, CH2 can be determined as behaving in a same or different manner depending on whether the following relation is true or false at a given check instant:
ΔV21=|V2−V1|<VTH
where VTH is a predefined threshold value.
Upon carrying out the above-illustrated step d), the method 1 comprises a step e) of carrying out a determination procedure DP to determine the configuration status of the input channels CH1, CH2, . . . , CHN based on behavior of the input voltages V2, . . . , VN of the remaining input channels CH2, . . . , CHN with respect to the input voltage V1 of the selected reference channel CH1.
In general terms, the determination procedure DP allows determining the input channel configuration of the inverter 100 properly observing the behavior of the input voltages at said input channels (more precisely at the input terminals of said input channels).
At a given check instant, upon the execution of the step b) of the method 1), a certain input current I1 flows along the reference input channel CH1 whereas null or lower input currents I2, . . . , IN flow along the remaining input channels CH2, . . . , CHN.
Referring to
As a consequence, the input voltage of possible remaining input channels electrically connected in parallel with the reference input channel CH1 will follow the input voltage V1 of the reference input channel CH1 thereby decreasing from its no-load voltage value VOC to the value V1=VA.
On the other hand, the input voltage of possible remaining input channels not electrically connected in parallel with the reference input channel CH1 will stably remain at its no-load voltage value VOC or will decrease to a value VQ higher than V1=VA (e.g. in a neighborhood of the voltage value VOC) as null currents or currents lower than the current I1=IA are allowed to flow along said input channels.
The physical connection arrangement of each input channel CH1, . . . , CHN can thus be determined by properly observing the behavior of the input voltages V2, . . . , VN of the remaining input channels CH2, . . . , CHN in relation to the input voltage V1 of the reference channel CH1.
More particularly, the configuration status of each input channel CH1, . . . , CHN can be determined by properly checking whether the input voltages V2, . . . , VN of the remaining input channels CH2, . . . , CHN decrease as the input voltage V1 of the reference input channel CH1.
As illustrated above, the voltage differences between each of the input voltages V2, . . . , VN of the remaining input channels CH2, . . . , CHN and the input voltage V1 of the reference channel CH1 may be calculated and compared with predefined threshold values to carry out such a checking activity.
Preferably, the above-mentioned step e) of the method 1 comprises a structured determination procedure DP to determine the input channel configuration of the inverter 100 on the basis of the of the detection data D (
Initially, the method 1 provides for considering the preliminary event, according to which only the input voltage V1 of the reference input channel CH1 decreases upon the execution of the step b) of the method 1.
If such a preliminary event is verified, the reference input channel CH1 cannot be electrically connected in parallel with any remaining input channel CH2, . . . , CHN of the inverter 100 as none of the input voltages V2, . . . , VN of said remaining input channels behaves (i.e. decreases) as the input voltage V1 of the reference input channel CH1, upon the execution of the step b) of the method 1.
This means that the reference input channel CH1 is an independent channel.
In view of the above, the determination procedure DP preferably comprises a step e.1) of determining that the reference input channel CH1 is an independent channel, if the input voltages V2, . . . , VN of the remaining input channels CH2, . . . , CHN do not decrease as the input voltage V1 of the reference input channel CH1.
In other words, according to the step e.1), the reference input channel CH1 is determined as an independent channel, if none of the input voltages V2, . . . , VN of the remaining input channels CH2, . . . , CHN decreases as the input voltage V1 of the reference input channel CH1 upon the execution of the step b) of the method 1.
At this level of the determination process, the subsequent steps of the determination procedure DP depend on whether the remaining input channels CH2, . . . , CHN include a single input channel or multiple input channels.
If a single remaining input channel (e.g. the step CH2) is present, this latter is necessarily an independent channel.
In this case, in fact, the inverter 100 would necessarily include two input channels CH1, CH2 only, one of which (the reference input channel CH1) has already been determined as an independent channel.
For this reason, upon the execution of the above mentioned step e.1), the determination procedure DP preferably comprises the following step e.2): if there is a single remaining input channel, determining that said single remaining input channel is an independent input channel.
Upon the execution of the step e.2), the determination procedure DP is terminated as it has been possible to determine the configuration of all the input channels (e.g. CH1 and CH2) of the inverter 100.
If the remaining input channels CH2, . . . , CHN include multiple input channels, no determination can be taken on said remaining input channels, even if the reference input channel CH1 has already been determined an independent input channel.
In fact, since the power converters C2, . . . , CN operatively associated to the remaining input channels CH2, . . . , CHN are deactivated or low currents flow said remaining input channels, the input voltages V2, . . . , VN of the remaining input channels CH2, . . . , CHN stably remain at their no-load voltage values or take values higher than the input voltage V1 and no information on their configuration can be derived from such a behavior. For example, they may be all configured as independent channels or some of them may be electrically connected in parallel with a same DC source.
For this reason, upon the execution of the above mentioned step e.1), alternatively with respect to the above-mentioned step e.2), the determination procedure DP preferably comprises the step e.3) of repeating the above mentioned steps a), b), c), d), e) for the remaining input channels CH2, . . . , CHN, if there is a plurality of remaining input channels CH2, . . . , CHN.
In practice, in this case, the method 1 is recursively executed for a new group of available input channels, which includes all the multiple remaining input channels CH2, . . . , CHN and which does not include the previously selected reference input channel CH1.
Obviously, during such a recursive execution of the method 1, a new reference input channel and new remaining input channels have to be selected among the remaining input channels CH2, . . . , CHN in accordance with the step a) of the method 1.
If the input voltages of one or more first remaining input channels CH2, . . . , CHi−1 of the inverter 100 decrease as the input voltage V1 of the reference input channel CH1, it means that the reference input channel CH1 and said first remaining input channels are electrically connected in parallel with a same DC source (formed by the coincident DC sources S2, . . . , Si−1) as their input voltages V1, V2, . . . , Vi−1 behave (i.e. decrease) in a similar way upon the execution of the step b) of the method 1.
For this reason, the determination procedure DP preferably comprises the following step e.4): if the input voltages V2, . . . , Vi−1 of one or more first remaining input channels CH2, . . . , CHi−1 decrease as the input voltage V1 of the reference input channel CH1, determining that the reference input channel CH1 and the first remaining input channels CH2, . . . , CHi−1 are parallel input channels.
At this level of the determination process, as logic alternatives to the above-described condition, the following possible events may occur:
In both these cases, it is necessary to check whether there are second remaining input channels (e.g. the input channels CHi, . . . , CHN) different from the first remaining input channels CH2, . . . , CHi−1 having input voltages Vi, . . . , VN that do not decrease as the input voltage V1 of the reference input channel CH1.
If there are no second remaining input channels CHi, . . . , CHN, the input voltage of which does not decrease as the input voltage V1 of the reference input channel CH1, the determination procedure DP is terminated.
Such an event, in fact, would necessarily imply that the above-mentioned first remaining channels CH2, . . . , CHi−1 (the configuration of which is already determined) include all the input channels of the inverter 100 different from the reference input channel CH1 (in practice all the above-mentioned remaining input channels of the inverter 100).
If there are second remaining input channels CHi, . . . , CHN, the input voltage of which does not decrease as the input voltage V1 of the reference input channel CH1, the subsequent determination steps of the determination procedure DP depend on whether said second remaining input channels include a single input channel or multiple input channels.
If the second remaining input channels of the inverter 100 include a single input channel, this latter is necessarily an independent channel.
In this case, in fact, such a second remaining input channel would be the only channel with an input voltage that does not decrease as the input voltages of the other input channels (i.e. the reference input channel and the first remaining input channel) of the inverter 100.
For this reason, upon the execution of the above mentioned step e.4), the determination procedure DP preferably comprises the following step e.5): if there is a single second remaining input channel, determining that said single second remaining input channel is an independent input channel.
Upon the execution of the step e.5), the determination procedure DP is virtually terminated as it has been possible to determine the configuration of all the input channels of the inverter 100.
If the second remaining input channels of the inverter 100 include multiple input channels, no determination can be taken on the configuration status of said input channels.
In fact, upon the execution of the step b) of the method 1, these second remaining input channels stably remain at their no-load voltage values or take values higher than the input voltage V1 and no information on their configuration can be derived from such a behavior.
For this reason, upon the execution of the above mentioned step e.5), the determination procedure DP preferably comprises the step e.6): if there is a plurality of second remaining input channels, repeating the above mentioned steps a), b), c), d), e) for said second remaining input channels.
In practice, in this case, the method is recursively executed for a new group of available input channels, which include the second remaining input channels CHi, . . . , CHN only and which does not include the reference input channel CH1 and the first remaining input channels CH2, . . . , CHi−1.
Obviously, during such a new recursive execution of the method 1, a new reference input channel and new remaining input channels have to be selected among said second remaining input channels CHi, . . . , CHN in accordance with the step a) of the method 1.
Referring now to
For the sake of simplicity, the following examples #1 to #5 (
Example #6 (
The inverter 100 is supposed to have two input channels CH1, CH2 electrically connected with corresponding DC sources S1, S2 and corresponding power converters C1, C2 that are supposed to be initially deactivated.
According to the step a) of the method 1, the input channel CH1 is selected as a reference input channel. As a consequence, the input channel CH2 represents the remaining input channel of the inverter 100 as defined above.
According to the step b) of the method 1, at a given check instant t1, the power converter C1 corresponding to the reference input channel CH1 is activated whereas the power converter C2 operatively associated to the remaining input channel CH2 is maintained deactivated.
According to the steps c)-d) of the method 1, detection data D related to the input voltages V1, V2 of the input channels CH1, CH2 are acquired and compared.
As it is possible to observe from
According to the steps e.1)-e.2) of the determination procedure DP, both the input channels CH1, CH2 are determined as independent input channels.
The determination of the configuration status of the input channels of the inverter 100 is completed.
In this example, the inverter 100 is arranged as in the example #1, i.e. it comprises two input channels CH1, CH2.
As it is possible to observe from
According to the step e.4) of the determination procedure DP, both the input channels CH1, CH2 are determined as parallel input channels.
The determination of the configuration status of the input channels of the inverter 100 is completed.
The inverter 100 is supposed to have three input channels CH1, CH2, CH3 electrically connected with corresponding DC sources S1, S2, S3 and corresponding power converters C1, C2, C3 that are supposed to be initially deactivated.
According to the step a) of the method 1, the input channel CH1 is selected as a reference input channel. As a consequence, the input channels CH2, CH3 represent the remaining input channels of the inverter 100 as defined above.
According to the step b) of the method 1, at a given check instant t1, the power converter C1 corresponding to the reference input channel CH1 is activated whereas the power converters C2, C3 operatively associated to the remaining input channels CH2, CH3, are maintained activated.
According to the steps c)-d) of the method 1, detection data D related to the input voltages V1, V2, V3 of the input channels CH1, CH2, CH3 are acquired and compared.
As it is possible to observe from
According to the steps e.4) and e.5) of the determination procedure DP, the input channels CH1, CH2 are determined as parallel input channels whereas the input channel CH3 is determined as an independent input channel.
The determination of the configuration status of the input channels of the inverter 100 is completed.
In this example, the inverter 100 is arranged as in the example #3, i.e. it comprises three input channels CH1, CH2, CH3.
As it is possible to observe from
According to the step e.1) of the method 1, the input channel CH1 is determined as an independent input channel.
However, the determination of the configuration status of the input channels of the inverter 100 is not completed at this level of the determination procedure.
In fact, no determination can be taken for the channels CH2, CH3 as their input voltages V2, V3 stably remain at their no-load values VOC following the activation of the power converter C1 at the check instant t1.
According to the step e.3) of the determination procedure DP, the steps a)-e) of the method 1 are recursively repeated for the input channels CH2, CH3 only.
According to the step a) of the method 1, the input channel CH2 is selected as new reference input channel. Accordingly, the input channel CH3 represents the new remaining channel of the inverter 100 as defined above.
According to the step b) of the method 1, at a given check instant t2, the power converter C2 corresponding to the new reference input channel CH2 is activated whereas the power converter C3 operatively associated to the new remaining input channel CH3 is maintained deactivated.
According to the steps c)-d) of the method 1, detection data D related to the input voltages V2, V3 of the input channels CH2, CH3 are acquired and compared.
As it is possible to observe from
According to the steps e.1)-e.2) of the determination procedure DP, both the input channels CH2, CH3 are determined as independent input channels.
The determination of the configuration status of the input channels of the inverter 100 is now completed.
The inverter 100 is supposed to have six input channels CH1, CH2, CH3, CH4, CH5, CH6 electrically connected with corresponding DC sources S1, S2, S3, S4, S5, S6 and corresponding power converters C1, C2, C3, C4, C5, C6 that are supposed to be initially deactivated.
According to the step a) of the method 1, the input channel CH1 is selected as a reference input channel. The input channels CH2, CH3, CH4, CH5, CH6 represent the remaining input channels of the inverter 100 as defined above.
According to the step b) of the method 1, at a given check instant t1, the power converter C1 corresponding to the reference input channel CH1 is activated whereas the power converters C2, C3, C4, C5, C6, operatively associated to the remaining input channels CH2, CH3, CH4, CH5, CH6, are maintained deactivated.
According to the steps c)-d) of the method 1, detection data D related to the input voltages V1, V2, V3, V4, V5, V6 of the input channels are acquired and are compared.
As it is possible to observe from
According to the steps e.4) and e.5) of the determination procedure DP, the input channels CH1, CH3, CH5 are determined as parallel channels.
However, the determination of the configuration status of the input channels of the inverter 100 is not completed at this level of the determination procedure.
In fact, no determination can be taken for the channels CH2, CH4, CH6 as their input voltages V2, V4, V6 stably remain at their no-load values VOC following the activation of the power converter C1 at the check instant t1.
According to the step e.6) of the method 1, the steps a)-e) of the method are recursively repeated for the input channels CH2, CH4, CH6 only.
According to the step a) of the method 1, the input channel CH2 is selected as new reference input channel. Accordingly, the input channels CH4, CH6 represent the new remaining channels of the photovoltaic inverter as defined above.
According to the step b) of the method 1, at a given check instant t2, the power converter C2 corresponding to the new reference input channel CH2 is activated the power converters C3, C6, operatively associated to the new remaining input channels CH4, CH6, are maintained deactivated.
According to the steps c)-d) of the method 1, detection data D related to the input voltages V2, V4, V6 of the input channels CH2, CH4, CH6 are acquired and compared.
As it is possible to observe from
According to the steps e.4) and e.5) of the determination procedure DP, the input channels CH2, CH4 are determined as parallel input channels whereas the input channel CH6 is determined as an independent input channel.
The determination of the configuration status of the input channels of the inverter 100 is now completed.
In this example, the inverter 100 is arranged as in the example #1, i.e. it comprises two input channels CH1, CH2.
According to the step a) of the method 1, the input channel CH1 is selected as a reference input channel. As a consequence, the input channel CH2 represents the remaining input channel of the inverter 100 as defined above.
According to the step b) of the method 1, at a given check instant t1, the power converters C1, C2 are controlled in such a way that the power converter C1 corresponding to the reference input channel CH1 is fed with a current I1 higher than a given threshold ITH and the power converter C2 operatively associated to the remaining input channel CH2 is fed with a current I2 lower than a given threshold ITH.
To this aim, as shown in
According to the steps c)-d) of the method 1, detection data D related to the input voltages V1, V2 of the input channels CH1, CH2 are acquired and compared.
As it is possible to observe in
According to the steps e.1)-e.2) of the determination procedure DP, both the input channels CH1, CH2 are determined as independent input channels.
The determination of the configuration status of the input channels of the inverter 100 is completed.
This example clearly shows that the determination of the configuration status of the input channels can be suitably carried out also in the general case in which the power converters C1, . . . , CN are controlled in such a way the input current flowing along the reference input channel is set higher than the current threshold ITH and the input currents flowing along the remaining input channels are set lower than said current threshold.
In this respect, further examples similar to examples #2 to #5 may be easily provided by simply considering different current profiles for the input currents I1, . . . , IN flowing along the input channels CH1, . . . , CHN.
The above examples clearly show how the input channel configuration of the inverter 100 can be determined based on the detection data D by observing behavior of the input voltages V1, . . . , VN of the input channels CH1, . . . , CHN following a selective current feeding of the input channels CH1, . . . , CHN, e.g. obtained through a selective activation and deactivation of the power converters C1, . . . , CN corresponding to said input channels or by controlling said power converters in such a way that said input channels are fed with currents having selected profiles.
According to a preferred embodiment of the invention, the method 1 comprises the step f) of storing information I indicative of the configuration status determined for the input channels CH1, . . . , CHN of the inverter 100.
Preferably, the step f) of the method 1 is carried out concurrently with the execution of the step e), for example each time the configuration status of an input channel is taken into consideration during the above-mentioned determination procedure.
The configuration information I attributed to the input channels CH1, . . . , CHN during the execution of the determination procedure DP is conveniently formed by suitable sets of bits (variable values) stored in a memory.
As an example, each input channel may be labeled as “independent”, “parallel” or “undetermined” depending on the determination taken on its configuration status or depending on the level reached in the decision process implemented by the determination procedure DP.
Of course, when the execution of the step e) is completed, all the input channels of the inverter 100 are expected to be labeled as “independent” or “parallel”.
The stored configuration information I is used by the control means 140 for controlling the operation of the inverter 100, e.g. for carrying out a MMPT regulation of the electric power generated and transmitted to the electric power distribution grid.
Conveniently, in its practical implementation, the method 1 is particularly adapted for being executed by data processing resources residing in the inverter 100.
Preferably, the method 1 is executed by the above-mentioned data-processing resources 160 of the control means 140 of the inverter 100.
The method, according to the present invention, provides several advantages with respect to the state of the art.
The method, according to the invention, allows automatically determining with high levels of accuracy the configuration status of the input channels of a photovoltaic inverter.
The photovoltaic inverter can thus behave as a “plug & play” apparatus capable of storing the required configuration information related to the configuration status of the input channels without the intervention of an external operator, simply carrying out the method of the invention at each power-up.
This feature allows achieving a remarkable reduction of the commissioning time and costs to put the photovoltaic inverter in condition for properly operating.
Additionally, an improvement of the overall control functionalities of the photovoltaic inverter can be achieved as human errors in setting the above-mentioned configuration information are avoided.
The method, according to the invention, is characterized by a high level of flexibility in its practical implementation. Thus, it may be successfully adopted in multi-channels photovoltaic inverters of different types, e.g. having different numbers of input channels.
The method, according to the invention, is of relatively easy implementation at industrial level. As an example, it may be easily carried out by processing devices on board the photovoltaic inverter, such as microcontrollers or DSPs.
| Number | Date | Country | Kind |
|---|---|---|---|
| 18150418.4 | Jan 2018 | EP | regional |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2018/086602 | 12/21/2018 | WO | 00 |
