EP4179614A1 - Method for detecting a fault of a photovoltaic inverter - Google Patents

Abstract

The invention relates to a method for detecting a fault of a photovoltaic inverter, the method comprising: - for at least one cyclic time profile of operation of the inverter, each cycle of the cyclic time profile comprising an outright disconnection of the inverter by a dry contact, followed by a reconnection of the inverter, obtaining a plurality of measurements of an electrical quantity indicative of an electrical efficiency of the inverter, each measurement being associated with a respective cycle of the cyclic time profile, - for at least one pair of cycles, determining an indicator of degradation of performance of the inverter, associated with the pair of cycles, on the basis of a comparison between the measurements obtained respectively associated with the cycles of the pair of cycles, and - detecting a present or future fault of the inverter on the basis of a comparison between at least one determined indicator and a predetermined threshold.

Description

Description

Title: Device and method for qualifying photovoltaic inverters by accelerated quantification of their reliability

Technical area

The present disclosure relates to the field of photovoltaic energy, and relates more specifically to methods for detecting failure of photovoltaic inverters and to computer programs, recording media and processing circuits allowing the implementation such detection methods.

Prior technique

[0002] In 2019, the cumulative and installed photovoltaic (PV) power worldwide reached 600 Gigawatts (GW). Experts predict that the symbolic bar of 1 Terawatts will be reached and crossed during 2022. Faced with such an accelerated pace of development and deployment of photovoltaic power plants, optimized operation and efficient management of the strongly growing number of solar assets are becoming issues with high technical and economic stakes. One of the ways to address such issues is that of preventive and corrective maintenance techniques and procedures.

[0003] The operations and maintenance (O&M) market is very buoyant, with rising demand, proportional to the development of installed capacity. Nowadays, O&M costs are estimated at around €8,000/MWp/year for ground-mounted photovoltaic power plants. In just a few years, the O&M service has become a separate market with its own landscape, trends and dynamics.

[0004] In addition, in mature photovoltaic markets, operating and maintenance revenues may exceed development and construction revenues.

SUBSTITUTE SHEET (RULE 26) [0005] Despite a very favorable economic context, the analysis and characterization of PV modules and power plants are today mainly carried out by qualitative methods, including visual tests or infrared and electroluminescence measurements. The degradation and performance loss modes of a solar asset are generally detected too late and their severity is poorly estimated. Consequently, the PV plants produce less, thus degrading the profitability of the solar asset in question.

[0006] The aggregation of historical data on the operation of PV power plants around the world shows that, of all the components of a photovoltaic power plant, the photovoltaic inverter has the highest frequency of failures. Additionally, and by default, the PV inverter holds the largest share of plant-wide energy loss. It should be noted that 50% of these losses are caused by only 5% of incidents. The criticality of the component studied is therefore key, and this is undeniably the case for PV inverters.

[0007] On the scale of a single inverter, 75% of energy losses occur at the critical nodes of the conversion chain, which is divided into two operating stages:

- the search for the maximum DC power point (PDC) of the PV installation, characterized by its efficiency, which will be noted as PMRRT, and

- the conversion of DC power into AC power, characterized by its efficiency, which will be denoted h DC/AC-

[0008] In summary, the degradation of the performance of photovoltaic power plants, in particular that of PV inverters, is suffered, detected late, and thus imposes purely corrective O&M.

Summary

The present invention improves the situation.

[0010] A method for detecting failure of a photovoltaic inverter is proposed, the method comprising:

- for at least one cyclic time profile of operation of the inverter, each cycle of the cyclic time profile comprising a clear disconnection of the inverter by a dry contact, followed by a reconnection of the inverter, obtaining a plurality of measurements of an electrical quantity indicative of an electrical efficiency of the inverter, each measurement being associated with a respective cycle of the time profile cyclic,

- for at least one pair of cycles, a determination of an inverter performance degradation indicator, associated with the pair of cycles, on the basis of a comparison between the measurements obtained respectively associated with the cycles of the pair of rounds, and

- detection of a present or future failure of the inverter on the basis of a comparison between at least one determined indicator and a predetermined threshold

The present invention therefore deals exclusively with the problem of the degradation of performance and the reliability of inverters, with the aim of proposing a solution that can be used for preventive and corrective purposes, making it possible to predict these problems before undergoing them or correct them after detection, through a rigorous qualification methodology before and after they are put into operation.

[0012] The method described makes it possible to monitor an inverter already installed, but also proposes to detect defective inverters before they are placed on the market.

[0013] The disclosed method therefore makes it possible to carry out preventive maintenance operations by early detection of reliability problems before the commissioning of the inverters as well as corrective maintenance operations on inverters for which performance problems have already been detected.

[0014] The characteristics set out in the following paragraphs can optionally be implemented. They can be implemented independently of each other or in combination with each other:

[0015] In one example, the input of the inverter is coupled to an electric generator and at least one cyclical time profile is predetermined and generated by the electric generator. [0016]Thanks to such an electric generator, it is possible for example to simulate the producible of a photovoltaic installation, and thus to apply, to an inverter at the output of production, a temporal profile alternating periods of cuts and periods representative of its future operating conditions in a photovoltaic power plant.

In one example, the method is implemented for at least two different predetermined cyclic time profiles applied successively.

[0018] Thus, by using two cyclic time profiles differing in the intensity of the stresses, it is possible, for example, to qualify an inverter both for standard operating conditions and for more demanding operating conditions.

[0019] In one example, the duration of the cycles is different for each predetermined time profile.

[0020] In one example, the duration of the connection intervals is different for each predetermined time profile.

[0021] In one example, the duration of the cut-off intervals is different for each predetermined time profile.

In one example, the number of cycles is different for each predetermined time profile.

The parameters mentioned above influence the intensity of the electrical stresses to which the inverter is subjected.

[0024] For example, the higher the frequency of clean disconnections, the more intensely the inverter is stressed.

[0025] Applying two different programs to the same inverter, having the same frequency of clear disconnections but different ratios between the respective durations of the connection intervals and the cut-off intervals makes it possible to perform a decoupling between the respective contributions, on the one hand , frank disconnections and, on the other hand, normal operation of the inverter in operation on the performance degradation of the inverter. So, he It is possible to derive both the calendar aging of the inverter and the aging linked to the number of cycles undergone by the inverter.

[0026] In one example, the input of the inverter is coupled to at least one photovoltaic panel and a cyclic time profile is generated by the photovoltaic panel exposed to an incident solar flux.

[0027] Thus, it is possible to qualify an inverter installed in a photovoltaic power plant and to quantify its performance while continuing to produce photovoltaic energy.

In one example, the method comprises:

- for at least two pairs of cycles of the cyclic time profile, a determination of an indicator of degradation of performance of the inverter, associated with the pair of cycles, on the basis of a comparison between the measurements respectively associated with the cycles of the pair of cycles, and obtaining an average value of a physical parameter during the pair of cycles, and

- a determination of the presence or absence of a correlation between the physical parameter and the performance degradation of the inverter on the basis of the determined indicators and the average values obtained.

[0029] Thus, it is possible not only to determine or predict a failure of the inverter, but also to identify the cause or causes (intrinsic or extrinsic). Identifying the causes of failure is useful not only to trigger preventive or corrective maintenance actions for a given inverter, but also to be able to identify, upstream, a potential recurring cause of failure of a fleet of inverters and the prevent.

In one example, the physical parameter is a temperature of the inverter measured by a temperature sensor.

In one example, the physical parameter is an irradiance of the photovoltaic panel measured by an irradiance sensor.

[0032] Having determined that such extrinsic factors are likely to cause a failure in the long term of a given inverter, it is possible to affect this inverter to a project where it will be subjected to less intense thermal or electrical stresses in order to optimize its lifespan.

In one example, the indicator is a total conversion efficiency of the inverter, defined as a convolution product of an AC/DC conversion efficiency of the inverter and a conversion efficiency at the maximum point power of the inverter, and the physical parameter is the AC/DC conversion efficiency of the inverter.

[0034]Thus, it is possible to determine an intrinsic cause of degradation of a given inverter and to replace or repair only the portion of power electronics concerned within the inverter.

[0035] A computer program is also proposed comprising instructions for implementing the above method when this program is executed by a processor.

[0036] A non-transitory recording medium readable by a computer is also proposed on which is recorded a program for the implementation of the above method when this program is executed by a processor.

[0037] A processing circuit is also proposed comprising a processor connected to a communication interface and to the above non-transitory recording medium.

Brief description of the drawings

[0038] Other characteristics, details and advantages will appear on reading the detailed description below, and on analyzing the appended drawings, in which:

Fig. 1

[0039] [Fig. 1] represents, in an exemplary embodiment, a photovoltaic installation.

Fig. 2

[0040] [Fig. 2] represents, in an exemplary embodiment, a flowchart of a general algorithm of a computer program for the implementation of a method for detecting failure of a photovoltaic inverter. Fig. 3

[0041][Fig. 3] represents, in an exemplary embodiment, the average daily temperature as well as the total efficiency of an inverter over a period of time.

Fig. 4

[0042] [Fig. 4] represents, in an exemplary embodiment, the total daily irradiance of a photovoltaic installation as well as the total efficiency of an inverter of this installation during a time period.

Fig. 5

[0043][Fig. 5] represents, in an exemplary embodiment, the efficiency hMRRt(ΐ)άb searching for the maximum power point as well as the total efficiency tot(t) of an inverter during a time period.

Description of embodiments

[0044] Reference is made to [Fig. 1] which represents, in one embodiment of the invention, an example of a photovoltaic installation.

The photovoltaic installation comprises a plurality of photovoltaic panels (1). Each panel or group of panels is made up of photovoltaic cells capable of converting solar energy into direct current (DC) electrical energy.

The energy delivered by the photovoltaic cells depends on a complex equation relating the solar radiation, the temperature, and the total resistance of the circuit, which leads to a nonlinear output power.

This electrical energy is first converted by a CNV DC/DC voltage converter (2) connected to the photovoltaic panels then by an OND inverter (4) connected to the DC/DC converter (2) by an HVDC bus (3 ). After conversion by the inverter, the electrical energy is delivered, at the output, to an electrical network. Intrinsically, an inverter is by definition an element based on power electronics. More precisely, the inverter comprises two stages of power electronics.

The first stage has a charge regulator function, which is capable of continuously analyzing the output of the photovoltaic cells in order to adjust the most appropriate resistance to be applied in order to supply the maximum power to the electrical network at the output. In other words, the first stage of power electronics ensures a choice of a maximum possible current/voltage pair.

The second stage, downstream, has a DC/AC converter function, which converts the DC current at the maximum power point into an AC current which is delivered to the electrical network at the output. The DC/AC conversion efficiency can be determined by a specific, experimental measurement, under standardized operating conditions.

[0051] Power electronics are highly sensitive to operating conditions and the nature of the stresses. Once installed in a photovoltaic power plant, the inverter is subject to two types of stress/constraints:

- thermal constraints (fluctuations in external temperature, strong variations in internal temperature), as well as

- electrical constraints (limitation instructions, open circuits, power cuts).

[0052] Naturally, inverters are exposed to a combination of these two types of stress. Irreversible degradation of the performance of the inverter is very often induced, directly impacting the search efficiency of the maximum power point and/or the DC/AC conversion efficiency, thus degrading the technical and financial performance of the photovoltaic power plant which supplies thus less energy to the electrical network.

[0053] Reference is now made to [Fig. 2], which represents a flowchart of a general algorithm of a computer program for the implementation of a method for detecting failure of a photovoltaic inverter. In order to qualify the operation of the inverter and to quantify its performance, it is proposed to subject the inverter to a combination of thermal stresses and electrical stresses.

The ambient temperature of the photovoltaic installation as a whole is therefore a thermal stress experienced. The internal temperature of the inverter is a thermal stress affected by the predetermined electrical stresses and typically results from energy dissipation by Joule effect.

The electrical stresses are predetermined and generated by a TR remote switch (5) connected to the OND inverter (4).

The TR remote switch (5) is controlled COM TR (S2) by a processing circuit comprising a processor CPU (7) connected to a memory MEM (8) and to a communication interface INT (6) to perform a succession clean disconnections and reconnections of the inverter (4).

[0058] The term "definite disconnection" means an abrupt variation in the power supply, without temporal damping. The inverter is thus switched off instantly. This clean disconnection can be implemented at the level of the AC electrical circuit at the input of the inverter or at the level of the DC electrical circuit at the output of the inverter.

This succession obeys a predetermined cyclical or periodic program which can be defined by four parameters, namely:

- the frequency of clean disconnections, or equivalently the duration of a cycle consisting of a cut-off period followed by an operating period,

- the duration of the TOFF inverter outage period between each clear disconnection and the subsequent reconnection,

- the duration of the operating period of the TON inverter between each reconnection and the subsequent clear disconnection, and

- the cumulative number of cycles, i.e. the cumulative number of clear disconnections or reconnections.

[0060] As an indication, a first proposed predetermined cyclical program can be defined as spreading over a total duration of 2 days, with a frequency of 4 daily outage periods, each outage period lasting one hour and being followed by a five-hour operating period, for a cumulative total of 8 clear disconnections and 8 reconnections.

A second predetermined cyclic program proposed, both more intensive and longer, can be defined as spreading over a total duration of 16 days, with a frequency of 24 daily cut-off periods, each cut-off period lasting 30 minutes and being followed by a period of operation of 30 minutes, for a cumulative total of 320 frank disconnections and 320 reconnections.

It is possible to select SEL PRG (S1) the predetermined cyclic program from a database of predetermined cyclic programs respectively associated, in a correspondence table, with operating conditions. Thus, it is possible to define different programs adapted according to the specificities of each photovoltaic installation and the resulting thermal and electrical constraints for the inverters of the installation. Thus, it is possible, from these specificities, known for each installation, to recommend to manufacturers, users or maintenance services to apply a given program.

A succession of different predetermined cyclic programs of different intensity can be implemented to successively test the robustness of the inverter for different operating conditions.

[0064] In general, as described above, an inverter installed in a photovoltaic power plant is subject to an accumulation of stresses, in particular thermal and electrical.

[0065] The demand doses of the inverters vary from one installation to another, in particular due to the climate. For example, some facilities are located in desert regions where sandstorms occur, resulting in higher thermal and mechanical stresses than facilities located in more temperate climates.

[0066] The solicitation doses of the inverters vary from one installation to another also because of the operating conditions and the modes of use of photovoltaic energy. Some installations may impose a specific configuration of the inverters in order to ensure voltage withstand in the face of voltage dips detected on the downstream electrical network. In addition, some installations have the option of storing part of the electrical energy produced, or not, by generating a reagent. Such installations are controlled differently from other installations capable only of supplying all of the electrical energy produced to the downstream electrical network.

For this reason, and to take account of these different stress levels, it is possible to propose different predetermined cyclic programs which differ in intensity. Depending on the operating conditions, the user can therefore rely on one of the programs offered to quantify the robustness and reliability of the inverter in line with the level of requirement and the intensity of the stresses in connection with the context of the photovoltaic installation.

[0068] Thus, it is possible, for example, to recommend a particular predetermined program making it possible to qualify an inverter in the way most suited to the geographical location of the photovoltaic installation in which it is installed.

In order to qualify the inverter in operation and, specifically, to quantify its performance during the application of the predetermined cyclic program, the photovoltaic installation is instrumented using various sensors measuring MES PARAM (S3 ) various parameters indicative of inverter operation and/or inverter operating conditions.

[0070] Alternatively, the inverter can be tested on leaving the production plant. In such a case, the photovoltaic installation is replaced by a DC current-voltage generator to simulate the producible of a photovoltaic installation.

It is thus possible to provide sensors of electrical quantities, for example:

- a first power meter measuring the PDC power at the input of the inverter, and - a second power meter measuring the PAC power at the output of the inverter.

[0072] It is also possible to provide additional sensors making it possible to detect values indicative of the operating conditions of the inverter, such as temperature or sunshine.

For example, temperature sensors can be installed at the input and/or output terminals of the inverter in order to estimate the internal temperature of the inverter.

For example, one can install a pyranometer measuring the global solar flux, that is to say the irradiance as a function of time.

It is thus possible to measure the temporal evolution of the temperature, of the sunshine or of other extrinsic parameters, undergone by the inverter during its operation.

The various sensors are connected to one or more data acquisition units which record and store the values measured by each sensor according to a predefined time step, for example in the form of time series of timestamped values.

[0077] Thus, during the implementation of the predetermined cyclic program, quantitative data is obtained and stored, making it possible to monitor the overall operation of the inverter, as well as optionally one or more extrinsic parameters such as the temperature or the 'sunshine.

[0078] Before exploiting this quantitative data to generate one or more indicators, or performance metrics, of the inverter, it is possible to apply APP FILT (S4), in post-processing, one or more quality filters of data.

[0079]0n can in particular apply a data completeness filter making it possible to detect a temporary absence of data from one or more sensors, and to quantify the completeness of the time series.

[0080]0n can also apply a uniqueness filter to detect and eliminate corrupt data and duplicates. It is also possible to apply a consistency filter making it possible to verify the uniformity of the measurement time steps, the dynamics of the data, the detection of static states and abnormal variations of the sensors.

[0082]0n can also apply a validity filter via a normalization of the measured data, for example within the meaning of the IEC 61724-1, 61724-2, 61724-3 standards or any other standard relating to the physical meaning of the measurements carried out such as the irradiance thresholds, temperature, performance ratio, DC power, AC power.

Once the data from the sensors has been obtained and filtered if necessary as indicated above, it is possible to determine DET PERF (S5) various metrics quantifying the performance of the inverter.

An example of such a performance metric can be the total conversion efficiency of the inverter as a function of time qtot(t), expressed by a simple ratio between the measurements of the output PAC and input PDC powers at each instant, i.e. qtot(t) = PAC/PDC. Other examples of performance metrics that can be calculated include, for example, maximum power point search efficiency or AC/DC conversion efficiency.

The performance metrics generally have a nominal value, which can be provided by the manufacturer of the inverter and/or determined for the new inverter under standard conditions of use and/or modeled by extrapolation from determined values. performance metrics on the UPS in service.

The values of the performance metric(s) vary as a function of the temporal evolution of the operating conditions. These variations are a combination of reversible fluctuations and irreversible drops in performance.

If the average performance of the inverter is below a predetermined threshold, it is thus possible to detect DET DEF / PERF (S61) that the irreversible drops in performance accumulated over time are excessive, corresponding to a present failure of the inverter. 'inverter. [0088] Various ACT/DEF actions (S8) can be implemented automatically following the detection of a present failure of an inverter. For example, it is possible to generate an alert, schedule an on-site maintenance intervention, disconnect the faulty inverter, connect another inverter in the installation as a replacement, etc.

The choice of the action to be implemented automatically can be linked to the type of inverter presenting a failure. Indeed, a photovoltaic installation can be based on string inverters, numerous and distributed so as to each manage, for example, a single photovoltaic panel. Alternatively, or in combination with string inverters, the photovoltaic installation can include centralized inverters, fewer in number and each managing a significant part of the installation.

[0090] Consequently, the most relevant actions to implement to overcome a failure of a string inverter can be its automatic disconnection supplemented by its replacement.

[0091] On the other hand, a faulty centralized inverter may be subject to automatic disconnection, but this disconnection will rather be supplemented by an in-depth analysis of the origin of the performance degradation and repair of the inverter.

[0092] Even if the average values of the inverter performance metric(s) do not indicate any present failure of the inverter, their evolution over time can make it possible to predict a future failure.

[0093] Indeed, it has been found experimentally that it was possible to differentiate the respective behaviors of functional and dysfunctional inverters subjected to the same predetermined cyclic program and, on this basis, to correctly predict a future failure of an inverter .

[0094] Indeed, the thermal and/or electrical stresses of an inverter have the consequence of degrading its performance metric(s). Thus, due to the repeated application of dry contacts, the performance metric(s) of the inverter decreases, at least partially irreversibly, during the implementation of the predetermined cycling program. If the inverter is functional, this degradation remains moderate and the performance metrics remain essentially constant during the implementation of the predetermined cyclic program.

[0096] Conversely, the performance of a dysfunctional inverter decreases more rapidly over time and is detrimental to the photovoltaic production of the installation.

Returning to the example of the total yield of the inverter as a performance metric of the inverter, to measure the extent of the irreversible degradations during the implementation of the predetermined program, it is possible for example to calculate the values total inverter yield for different program cycles.

For example, the total efficiency values can be calculated at the start of each operating period.

These values can then be compared with a reference value, or can be compared with each other.

For example, it can be considered that if, at the start of a given operating period, the value of ntot has crossed a predefined threshold, then a future failure of the inverter is to be expected.

This predefined threshold can be an absolute threshold, a threshold relating to a nominal value of ntot, or a threshold relating to a previously calculated value of ntot.

[0102] In general, for an inverter subjected to moderate stresses, an irreversible degradation rate of around 0.75% can be expected. In order to take into account the cases of strong stresses, this predefined threshold can correspond for example to a reduction of ntot greater than 1% in absolute value.

In other words, we can consider that:

- the ideal total efficiency of the inverter is fixed at 100% by reference,

- the efficiency of the inverter is calculated at an initial instant to then at a later instant t, then - if the difference tot(t) - ntot(to) between these calculated values is greater in absolute value than a predetermined threshold, for example 1% in absolute value, therefore 1% of the ideal total efficiency of the inverter, then one predicts PRD DEF/PERF (S62) a future inverter failure, and

- if, conversely, the difference h tot(t) - ntot(to) between these calculated values is less than or equal in absolute value to the predetermined threshold, then the inverter is considered compliant.

The predefined threshold can be set generally or specifically for each photovoltaic installation, or even specifically for each predefined cyclic program, by various known methods.

[0105]0n can cite for this purpose in particular statistical methods or learning methods from a large number of tot values calculated as part of the qualification of a fleet of inverters.

In an exemplary embodiment, the origin of a failure or loss of performance of the inverter (whether this is present and detected or future and predicted) can be identified ID SRC DEF (S7) by examining, alone or in combination, different extrinsic (like temperature or irradiance) and/or intrinsic (like h MPPT OR HDC/AC) factors. Thus, it is possible to determine whether a loss of performance of the inverter is exclusively extrinsic, or on the contrary at least partially intrinsic.

For example, since the inverter is equipped with temperature sensors at its terminals, it is possible to calculate, for each measurement time step, the average temperature recorded by the various sensors.

For each day, it is possible to calculate an average daily temperature of the inverter as being the daily average of the average temperatures respectively calculated for each average temperature step.

[0109]0n now refers to [Fig. 3] which represents, in an exemplary embodiment, the average daily temperature of an inverter as a function of time during a time period of 20 days, as well as the total yield of this same inverter during this same time period , as calculated as previously exposed. The terms “data extracts” appearing on the abscissa axis of [Fig. 3], as well as [Fig. 4] and [Fig. 5] refer to specific days in the time period.

[0110]During the time period in question, the inverter is subjected to cycles of clear disconnections and reconnections according to a succession of two predetermined cyclic programs differing from each other in their intensity.

In this example, daily average temperature fluctuations are observed throughout the time period, of the order of a few degrees, around an average value of 33.5°C. The thermal stresses are therefore not constant over the entire time period studied.

[0112] In parallel, from the ninth day, a gradual loss of performance of the inverter is observed. The total return decreases, from an initially stable value of about 96.5%, to about 91.5%.

In this example, no correlation can be established between the average daily temperature variations and the loss of performance of the inverter. Thus, the cause of the performance degradation cannot, in this example, be attributed to the temperature of the inverter.

[0114] In some cases, the evolution of the average daily temperature may present a linear correlation with the evolution of the loss of performance of the inverter. The average daily temperature is then, in these cases, an extrinsic factor of degradation of the performance of the inverter.

In an exemplary embodiment, the installation being equipped with a pyranometer, the total daily irradiance received can be calculated by temporal integration of the solar flux measurements accumulated during a day.

[0116] We now refer to [FIG. 4] which represents, in an exemplary embodiment, the total daily irradiance of a photovoltaic installation as a function of time during a time period of 20 days, as well as the total efficiency of an inverter of this installation during of this same time period, as calculated as described above. In this example, the inverter is subjected to the same succession of predetermined cyclic programs as in the example of [FIG. 3].

In this example, there are fluctuations in total daily irradiance throughout the time period, of the order of 10%, around an average value of 4.3×10 ⁵ W/m ² .

These fluctuations in total daily irradiance result in a similar fluctuation in the power factor of the inverter. In fact, the power factor of the inverter, that is to say the ratio between the real output power of the inverter and the nominal output power of the inverter, is linearly correlated with the irradiance. In general, the electrical stresses to which the inverter is subjected depend on the irradiance and, as such, vary over time.

In this example, we observe in parallel from the ninth day a gradual loss of performance of the inverter. The total return decreases, from an initially stable value of about 96.5%, to about 91.5%.

In this example, no correlation can be established between the variations in total daily irradiance and the loss of performance of the inverter. Thus, the cause of the performance degradation cannot, in this example, be attributed to irradiance.

In some cases, the evolution of the total daily irradiance can present a logarithmic correlation with the evolution of the loss of performance of the inverter. The total daily irradiance is then, in these cases, an extrinsic factor in the degradation of the performance of the inverter.

[0123] If it turns out that extrinsic factors are not the cause of the reduction in the total efficiency of the inverter, a methodology is proposed below for identifying the source of intrinsic degradation.

As already indicated above, and from an intrinsic point of view of the inverter, HtotesX the convolution between PMRRT QC qoc/Ac. The identification of the exact origin of the source of intrinsic degradation therefore requires a decoupling between hMRRt and HDC/AC in order to distinctly quantify their effect on h _fof . The efficiency h MPPT(Î) of searching for the maximum power point as a function of time is the ratio of the power Poc(t) at the output of the inverter as a function of time by the power PMPP(Î) of the point maximum operation reached by the inverter as a function of time.

The power PDC(Î) at the output of the inverter can be measured by a power meter as already explained.

[0127] The power PMPP) of the maximum operating point can be calculated using a photovoltaic production calculation model powered by meteorological data acquired by sensors of the photovoltaic installation and by information characteristic of the photovoltaic installation such as the power and number of photovoltaic modules, their inclination and their orientation.

The efficiency noc/Ac(t) of converting DC power into AC power can either be measured experimentally under standardized operating conditions, or be calculated by taking the ratio of the total efficiency tot(t) as a function of the time by the efficiency PMRRTA) of search for the maximum power point as a function of time.

[0129] We now refer to [FIG. 5] which represents, in an exemplary embodiment, the efficiency nMPPr(t) as well as the total efficiency ntot(t) of an inverter subjected to the same succession of predetermined cyclic programs as in the examples of [Fig. 3] and [Fig. 4].

It can be seen that the variations of the total efficiency and those of the efficiency of searching for the maximum power point are correlated in this example in a linear manner. Indeed, during the first days of the time period represented, h MPPT and ht _ô t both remain constant. Then, a gradual decrease in ht _ô t is observed, and is associated with a simultaneous decrease, and of substantially identical amplitude, in PMRRT.

In this example, it can be considered that the degradation factor of the total efficiency of the inverter is an intrinsic source, namely the efficiency HMPPr(t) of searching for the maximum power point. In general, the search for extrinsic or intrinsic sources of performance degradation of an inverter is carried out by the search, which can be automated, of a correlation, for example linear or logarithmic, between the temporal evolution of the extrinsic quantity or concerned intrinsic and the temporal evolution of the performance metric of the inverter.

If it is concluded that the source of degradation of the performance of the inverter is intrinsic and that the decrease in tot between the start and the end of the predetermined cyclic program(s) implemented exceeds a predetermined threshold, then the inverter in question is considered as a major source of AC energy loss for the photovoltaic power plant.

[0134] In the context of tests in the production plant, the product in question is not qualified and is discarded. Further analyzes can be carried out to identify and repair the affected components if necessary.

In the context of a measurement in a photovoltaic power plant, the inverter in question presents a high risk of failure and can be automatically disconnected. Corrective maintenance can also be scheduled to repair the faulty inverter. Alternatively, the inverter in question can be replaced by a qualified inverter in the production plant.

Claims

Claims

[Claim 1] A method of detecting failure of a photovoltaic inverter, the method comprising:

- for at least one cyclic time profile of operation of the inverter, each cycle of the cyclic time profile comprising a clear disconnection of the inverter by a dry contact, followed by a reconnection of the inverter, a obtaining (S3) of a plurality of measurements of an electrical quantity indicative of an electrical efficiency of the inverter, each measurement being associated with a respective cycle of the cyclic temporal profile,

- for at least one pair of cycles, a determination (S5) of an indicator of degradation of performance of the inverter, associated with the pair of cycles, on the basis of a comparison between the measurements obtained respectively associated with the cycles of the pair of cycles, and

- detection (S61, S62) of a present or future failure of the inverter on the basis of a comparison between at least one determined indicator and a predetermined threshold.

[Claim 2] A method according to claim 1, wherein the input of the inverter is coupled to an electric generator and at least one cyclic time profile is predetermined and generated by the electric generator.

[Claim 3] Method according to claim 2, implemented for at least two different predetermined cyclic temporal profiles applied successively.

[Claim 4] A method according to claim 3, wherein the duration of the cycles is different for each predetermined time profile.

[Claim 5] A method according to claim 3 or 4, wherein the duration of the connection intervals is different for each predetermined time profile.

[Claim 6] Method according to one of Claims 3 to 5, in which the duration of the cut-off intervals is different for each predetermined time profile.

[Claim 7] Method according to one of Claims 3 to 6, in which the number of cycles is different for each predetermined time profile.

[Claim 8] A method according to claim 1, wherein the inverter input is coupled to at least one photovoltaic panel and a cyclic time profile is generated by the photovoltaic panel exposed to incident solar flux.

[Claim 9] A method according to claim 8, comprising:

- for at least two pairs of cycles of the cyclic time profile, a determination of an indicator of degradation of performance of the inverter, associated with the pair of cycles, on the basis of a comparison between the measurements respectively associated with the cycles of the pair of cycles, and obtaining an average value of a physical parameter during the pair of cycles, and

- a determination of a presence or absence of correlation between the physical parameter and the degradation of performance of the inverter on the basis of the determined indicators and the average values obtained.

[Claim 10] A method according to claim 9, wherein the physical parameter is a temperature of the inverter measured by a temperature sensor.

[Claim 11] A method according to claim 9, wherein the physical parameter is an irradiance of the photovoltaic panel measured by an irradiance sensor.

[Claim 12] A method according to claim 9, wherein:

- the indicator is a total conversion efficiency of the inverter, defined as a convolution product of an AC/DC conversion efficiency of the inverter and a conversion efficiency at the maximum power point of the inverter , and

- the physical parameter is the AC/DC conversion efficiency of the inverter.

[Claim 13] Computer program comprising instructions for implementing the method according to one of Claims 1 to 12 when this program is executed by a processor.

[Claim 14] Non-transitory recording medium readable by a computer on which is recorded a program for implementing the method according to one of Claims 1 to 12 when this program is executed by a processor.

[Claim 15] Processing circuit comprising a processor PROC (100) connected to a communication interface COM (300) and to a non-transitory recording medium MEM (200) according to claim 14.