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Article

Experimental Performance Evaluation of a PV-Powered Center-Pivot Irrigation System for a Three-Year Operation Period

by
Juan Ignacio Herraiz
1,2,
Rita Hogan Almeida
1,
Manuel Castillo-Cagigal
2 and
Luis Narvarte
1,*
1
Instituto de Energía Solar–Universidad Politécnica de Madrid, C/Nicola Tesla s/n, 28031 Madrid, Spain
2
Qualifying Photovoltaics, C/Alan Turing 1, 28031 Madrid, Spain
*
Author to whom correspondence should be addressed.
Energies 2023, 16(9), 3654; https://doi.org/10.3390/en16093654
Submission received: 23 March 2023 / Revised: 17 April 2023 / Accepted: 21 April 2023 / Published: 24 April 2023
(This article belongs to the Special Issue Grid and Photovoltaic Powered Pumping Systems)

Abstract

:
High-power diesel-based or grid-connected irrigation systems are being replaced by battery-free, high-power stand-alone Photovoltaic Irrigation Systems (PVIS) that reduce energy costs by up to 80% and for which no experimental performance data are available. The operation of PVIS is affected by various factors, some unrelated to the quality of the PV system itself, that generate losses that affect their performance: losses that vary with the crop and its irrigation period, losses intrinsic to the PVIS design, and losses that happen as a consequence of the behavior of the end-user. To better understand the impact of each type of loss, the traditional performance ratio was factorized. This paper provides the PV community with experimental data on the performance of a battery-free 160 kWp PV-powered constant-pressure center-pivot irrigation system. The system was analyzed over three years of real operation, during which the performance ratio ranged from 49.0 to 53.2%.

1. Introduction

Stand-alone photovoltaic (PV) pumping systems have been present in the world since the 1970s, when Dominique Campana coordinated the installation of the first PV water pumping system in Corsica, France [1]. Father Bernard Vespieren, director of the non-governmental organization “Mali Aqua Viva” in Mali and one of the first visitors to the Corsica pumping system, introduced the first PV pump in Africa in 1977 [2].
Although these first experiences used ad hoc DC drivers to couple the pumps to the PV generators, innovations like the one presented by [3] allowed the use of standard frequency converters to feed standard AC centrifugal pumps. The power of these stand-alone PV pumping systems was limited to a few tens of kW due to the intermittent character of solar irradiance until five years ago, as can be seen in research from that period [4]. Sudden variations in irradiance caused by shadows from passing clouds made it impossible to ensure the stability of the FC of high-power PV pumping systems and led to control instabilities and sudden stops of the FC, producing water hammers in the hydraulic system and over-voltages between the FC output and the motor pump.
Despite this, these relatively small-power pumping systems have been widely used throughout the world for various applications, such as human drinking water supply [5], water supplies for livestock [6], or irrigation of crops [7,8].
They have also attracted the attention of researchers, who have investigated various technical aspects related to the optimization of their design based on the simulation of different systems like direct pumping [9], drip irrigation [10,11], multi-pumping [12,13], floating PV systems [14], and methodological aspects [15]. Other studies have been related to their control, such as the tuning of the PID control of the frequency converter [16], the application of artificial intelligence to the prediction of their productivity [17,18], the assessment of their performance [19,20] or its prediction [21], the development of different sizing methods [22,23] or simulation tools [24], the integration of storage [25], or the technical feasibility in different regions [26,27].
The economic viability of these pumping systems has also been researched. For example, in [28], the authors evaluated the socio-economic and climatic impact of PV drip and sprinkler irrigation systems, reporting savings of up to 66% in kWh cost. Others have explored the best ways to finance them, such as [29], presenting solutions based on blockchain technology to produce financial instruments suited to attracting investors to PV pumping projects. Others have explored the policy frameworks that may favor the implementation of irrigation systems [30]. Others have assessed PV pumping systems as a tool to reduce the environmental impact of agriculture [31].
The rising energy costs of modernized agriculture in the last few years have increased the need to expand the power of PV pumping systems for large-scale irrigation. The innovations developed in the framework of a European project [32], solving problems associated with PV power intermittences without the need for batteries [33], allowed the implementation of stand-alone high-power photovoltaic irrigation systems (PVIS) [34] that are not only economically feasible but also environmentally sustainable [35]. An alternative solution was the integration of batteries [36], but it was found to not be economically feasible for high power applications.
Prior work on performance has been focused on grid-connected PV systems, where performance basically depends on the quality of the system itself. Experience in its calculation and a deep knowledge of the experimental values of the most used performance indices, such as the Performance Ratio (PR), exist in the literature [37]. There are also experimental performance data for small power PV irrigation systems, such as those reported by [19] (monthly PR values between 59.7% and 93.1%). In the case of high-power PVIS, there is a lack of experimental data on their performance in the literature. Furthermore, the operation of high-power PVIS is limited by external factors other than their quality, and, therefore, the use of performance indices like the PR needs to be reconsidered. In order to quantify and better understand the impact of these external factors on performance, in 2018, Almeida et al. [34] proposed factorizing the traditional PR into various utilization ratios. The new indices considered different types of losses: losses strictly related to the PV system itself (PRPV); losses that vary with the crop and the irrigation period (URIP); those intrinsic to the design of the PV generator and the hydraulic infrastructure (URPVIS); and losses that occur as a consequence of the behavior of the irrigator (UREF) [34].
However, given the recent market introduction of PVIS, there are still very few publications reporting experimental PR values and even fewer on the values of the indices resulting from PR factorization. So far, data have only been published for two PVIS pumping to water pools (at variable pressure and water flow) [38], and no data are known for PVIS pumping at a constant flow and pressure, like the ones using pivots for irrigation. The characteristics of constant flow and pressure, in which the working frequency and the power consumed by the pump are constant, point to a PR lower than that of PVIS pumping to a water pool, but this has not been experimentally proven.
In order to address the limitations of prior work on the experimental performance of high-power PVIS, this paper provides experimental performance data for a PV-powered center-pivot PVIS working at a constant-pressure over a three-year period, adding to the knowledge of the expected performance of this kind of system. Experimental data are crucial since knowing the expected performance values is key to establishing quality thresholds in technical specifications and quality control procedures in the context of contractual frameworks for the sale and installation of high-power PVIS. Additionally, in this paper, the performance was evaluated both under stable irradiance conditions and also under conditions of fluctuating PV power from 2019 to 2022, quantifying the different utilization factors relevant to assessing the effect of external factors on the performance of high-power PVIS.
The paper is structured as follows: after the introduction, the materials and methods section describes the PVIS under study, the performance indices to be calculated, and the way the data were filtered and processed. Section 3 presents the results of the performance evaluation. Section 4 discusses the results, and Section 5 summarizes the conclusions obtained and proposes some future lines of research.

2. Materials and Methods

2.1. Description of the PVIS under Study

2.1.1. The Pre-Existing Irrigation System

The irrigation system (IS) was located in Alaejos, Spain (41°16′23.4″ N, 5°16′48.8″ E) and belonged to the cooperative “Estrella de San Juan”. It is used to irrigate a total area of 88 ha.
Figure 1 presents the pre-existing IS, which consisted of a diesel generator feeding two frequency converters. Each FC fed one of two pumps: a 92 kW submersible pump (Caprari–E10S50S/6C + MAC10125DS-8V), pumping water from a 140 m deep borehole to an elevated water tank of 1000 m3, and a 30 kW surface centrifugal pump (Caprari–MEC-AS2/80A + FELM 30KW 2P), pumping water from the tank to the irrigation network at the constant-pressures required by a set of four pivots.

2.1.2. The New PVIS

The new PVIS consisted of a 160 kWp PV generator, divided into eight North–South horizontal trackers, and three additional FCs: a 110 kW FC that fed the 92 kW submersible pump (hereinafter, “pumping FC”), a 37 kW FC that fed the 30 kW pump (hereinafter, “irrigation FC”), and another 37 kW FC used to feed the motors that move the pivots and work at a constant frequency of 50 Hz to simulate an electrical grid (hereinafter, “pivots FC”). The motors that drive the pivots are always on during irrigation. Their average consumption is 4.5 kW, but current peaks occur when the motors start and stop. The pivots FC is oversized to withstand these peaks. After the PVIS commissioning, the actual power of the PV generator was measured at 150.3 kWp. Figure 2 shows the configuration of the PVIS. Even though it was designed to replace the previous one, it was decided to keep the diesel generator and the old IS for greater irrigator confidence.
By definition, the PVIS is considered a stand-alone PV pumping system. However, since the pre-existing IS was kept, the whole PVIS could operate in three operation modes that the user could manually choose:
  • PV mode: the entire IS is fed by the PV generator;
  • PV/Diesel mode: pivots and the irrigation pump are fed by the PV generator while the borehole pump is fed by the diesel generator;
  • Diesel mode: the diesel generator supplies the required power.
The IS was used in PV mode to pump the maximum volume of water during the day, using the diesel generator at times of low radiation or at night when the PV system could not cover all the water needs of the crop.
The PVIS included an external programmable logic controller (PLC) that, depending on the end-user irrigation needs, the selected operation mode, the estimated available PV power, and the borehole and tank water levels, controlled the start and stop of the FCs. The PLC estimated the available PV power from irradiance measurements in the plane of the PV generator and cell temperature according to a maximum power point model [37] and gave the start order to the irrigation FC, to the pumping FC, or to both. Whenever the irrigator wanted to irrigate, the irrigation FC had priority over the pumping FC in case there was not enough PV power to make both pumps work. The PLC controlled the start and stop of the FCs based on hysteresis logic and a set of thresholds: one start threshold and one stop threshold to operate each FC. When the estimated available power was higher than the first start threshold (35 kW), the PLC sent a start signal to the irrigation FC, and the irrigation pump started operating. Another start signal was sent to the pumping FC when the estimated PV power was greater than a second start threshold (110 kW). If the estimated PV power fell below any stop threshold (51 kW for the second FC and 30 kW for the first one) during a 60 s time interval, a signal was sent to the corresponding FC to stop. Whenever the irrigation FC was on, the pivot FC was also on to power the motors that kept the pivots moving. Figure 3 schematically shows this hysteresis cycle.
Furthermore, in order to avoid start/stop cycles due to tank water levels, another hysteresis control based on four thresholds was used. When the tank water level was below a minimum threshold (L1) of 5% of the tank capacity, the tank was considered empty, and the irrigation FC was stopped. It was only started by the PLC when the tank water level reached a second threshold (L2), 10% of the tank capacity. Similarly, when the tank water level reached a maximum threshold (L4), 100% of the tank capacity, the pumping FC was stopped and only restarted when the water level dropped below L3 (90% of the tank capacity).
Besides the PLCs operating logic, all FCs had their own control programs. The pumping FC was controlled by a Maximum Power Point Tracking (MPPT) routine that maximized the efficiency of the PV production. The irrigation FC ran a pressure control routine to keep pressure at the irrigation network constant (there were three different pressure set points: 3, 4, and 5 bar, according to the pivot being used). In addition, the pivots FC was parameterized to work continuously at 50 Hz, simulating the grid. All FCs had passing cloud routines that allowed the PVIS to not be destabilized by fast irradiance fluctuations.
Figure 4 shows an aerial view of the PVIS, displaying the PV generator, the 1000 m3 elevated water tank or water pool, the FC house, and the irrigation and borehole pumps.
The PVIS was monitored by means of one-minute records of the output frequency, direct current (DC) voltage (VDC), DC current (IDC), DC power (PDC), alternating current (AC) voltage (VAC), and AC current (IAC) of the irrigation and pumping FCs, FC status, pressure and pressure set point for the irrigation network, irradiance (G), and module temperature (Tc).

2.2. Indicators Used to Assess the PVIS in Real Operating Conditions

The PR [37] has been traditionally used to analyze the performance of PV grid-connected plants. It is defined as
P R = E P V / ( ( P * / G * ) G d t ) ,
where P* is the peak power of the PV generator, G* is the irradiance under standard test conditions (1000 W/m2), G is the irradiance on the plane of the PV generator, and EPV is the energy produced by the PV system. Due to their specificities, high-power PVIS include PR losses not only related to the quality of the PV system itself but also to the crop and its irrigation period (IP), the intrinsic characteristics of the PVIS design, the hydraulic infrastructure, and external circumstances that may affect the PR, like irrigator decisions. Considering these, the PR can be expressed as [34]
P R = E P V P * / G * × 1 G d t × I P G d t I P G d t × G u s e f u l d t G u s e f u l d t × G u s e d d t G u s e d d t ,
where
  • IP is the irrigation period determined by the relationship between water needs, pumping capacity, and pumped water storage capacity in the case of pumping to a water tank and by the water needs of the crop and climatic conditions in the case of direct pumping;
  • Guseful (Figure 5c) is the irradiance required to deliver the power needed to elevate water to the water tank or to pump a given flow rate of water at the constant-pressure required by the pivots during the IP. It is determined by the relationship between the PV generator nominal power (P*), the PV generator supporting structure, and the characteristics of the PVIS. When the available irradiance is below a minimum threshold, the pumps cannot start because there is not enough power. When the available irradiance is above Guseful, part of the irradiance is wasted because the PV generator cannot supply more power than that consumed by the pump working at its nominal power;
  • Gused (Figure 5d) is the irradiance effectively used by the PVIS and depends on external circumstances like the availability of water or the irrigator’s decisions about whether to irrigate or not.
Equation (2) can be rewritten as [34]
P R = P R P V × U R I P × U R P V I S × U R E F ,
where
P R P V = E P V P * / G * × 1 G u s e d d t ;   U R I P = I P G d t G d t ;   U R P V I S = G u s e f u l d t I P G d t ;   U R E F = G u s e d d t G u s e f u l d t
PRPV is the PR considering losses strictly related to the PV system itself; URIP is the utilization ratio considering losses related to the irrigation period; URPVIS is the utilization ratio considering losses related to the PVIS design (type of IS, the ratio PV peak power—PV power required for irrigation, the tracking geometry, and the accuracy of the PLC control algorithms); and UREF is the utilization ratio considering losses related to the irrigator’s decisions.
In addition to the PR, Herraiz et al. [38] described the importance of two other indices to assess the correct functioning of PVIS: the number of abrupt stops and the passing cloud resistance ratio. The number of abrupt stops counts FC stops that occur suddenly and without control, as opposed to those initiated and controlled by the PLC or the FC itself that are performed gradually [38]. Under normal operating conditions, FCs stop in a controlled way. Abrupt FC stops are due to PVIS control instabilities caused by PV power quick intermittences or by a malfunction of the control. Distinguishing abrupt stops from controlled stops is important to correctly classify the losses associated with each stop. An abrupt stop is considered a PVIS malfunction, and the resulting losses are accounted for in the PRPV. Conversely, losses associated with controlled stops are accounted for in the URPVIS as they are related to the PVIS design. In order to distinguish between abrupt and controlled stops, it is necessary either that the monitoring system records information about the type of stop or that the PVIS is monitored by means of one-second records.
The passing cloud resistance ratio (σcloud) is defined as σ c l o u d = #   r e s i s t e d   c l o u d s / #   c l o u d s , where “# resisted clouds” is the number of passing clouds (big PV power fluctuations in short periods) that do not lead to FC abrupt stops and ”# clouds” is the total number of passing clouds in a specific period of time [38]. In order to calculate this index, a monitoring system with one-second records is required.

2.3. Data Filtering

The effects of data availability, filtering, and quality are becoming increasingly important in the PV sector, both in the literature and in industry [39,40,41]. The number of PV systems and their size are undergoing exponential growth in all areas, causing management and analysis procedures to become more complex. Data quality affects performance calculations. The quality of operating condition measurements is particularly relevant since the linearity of these variables with respect to the power shown by the models constitutes a powerful indicator of anomalies. To ensure adequate data quality, operating conditions and production data were filtered using three different types of filters, as stated in the IEC standard IEC-61724-2 [42]:
  • Range filter. This filter discards all values outside an established range for each analyzed variable. Minimum and maximum thresholds are defined, and any data that do not meet the requirements are removed. The threshold values are defined according to the season of the year. Therefore, there are four filter ranges for Spring, Summer, Autumn, and Winter.
  • Dead Value Filter. This type of filter discards frozen values, assuming that variables that maintain their value over time have abnormal behavior. Two parameters are required to implement it: the necessary minimum variation between analyzed periods to consider that a value is not frozen, and the minimum threshold from which the filter is applied (for example, the dead value filter may be applied to the measured power only when it is greater than zero).
  • Abrupt Change Filter. Analyzes the variation of the values of each variable between two-time intervals, discarding all values whose variation exceeds a certain threshold. This filter removes values that have changed faster than what is considered normal.
The previous filters were used to filter outliers from normalized data and try to eliminate measurement errors and noise, especially in operating condition variables (such as irradiance and temperature) and also in other critical production variables such as current, voltage, and power. In addition to these filters, coherence filtering was applied to remove inconsistent values, such as night-time irradiance values greater than zero.
Another major problem in the monitoring of stand-alone PVIS is the loss or absence of data. The causes can be multiple, including measurement problems, communication failures, problems in the data acquisition system, or outputs of the applied filters. This lack of data affects performance evaluation and monitoring fault detection, leading to a reduction in the PV system’s lifetime. As in data filtering, data losses are especially relevant when they affect operating conditions. Loss of meteorological data causes underestimation of in-plane irradiation (and overestimation of PR), while gaps in electrical data could be filled and still estimate with precision the energy yield. This study solved the problem of missing data by representing it as null values to clearly differentiate missing values from other types of problems when analyzing the data and by excluding the affected periods from processing.

2.4. Data Processing

After filtering the data were processed to obtain the performance indices. The first step of this process aimed to identify FC stops and whether these stops were controlled or abrupt. One FC stopped because its status changed from “running” to “stopped”. Moreover, a specific status indicated that a stop was abrupt, thus distinguishing controlled stops from abrupt stops. As stated above, distinguishing abrupt from controlled stops is important to correctly classify the losses associated with each stop. An abrupt stop is considered a PVIS malfunction, and the resulting losses are accounted for in the PRPV. Conversely, losses associated with controlled stops are accounted for in the URPVIS, as they are related to the PVIS design, or in the UREF, when they are a consequence of the irrigator’s decisions. Stops for PVIS maintenance receive special treatment. Preventive maintenance actions have to take place outside the IP or at night in order to not affect the PR. Preventive maintenance actions during the IP and during the daytime were accounted for in the UREF as a decision of the irrigator. Finally, corrective maintenance actions (a stop for the repair of malfunctioning equipment) are accounted for in the PRPV. However, several situations have been detected that hinder this processing due to the limitations of the monitoring of the PVIS under study. On the one hand, there are situations in which the FC status field indicates that the FC is stopped, but the rest of the variables (frequency, IDC, VDC...) show the opposite. To compensate for this, a double validation by status and IDC was performed for each FC. On the other hand, situations involving the abrupt stop of an FC are not always recorded. The monitoring system collected data every minute and stored the value of each variable at the precise moment it was recorded. It is possible that an abrupt stop occurred, but the FC status variable was not picked up until several seconds later. In that interval, the FC status could have changed from abrupt to controlled, masking the type of FC stop. It is also possible that a FC stops abruptly during the start-up process and the start-up status is not registered.
PVIS with one-second monitoring allowed us to identify, in addition to abrupt and controlled stops, passing clouds over the PV generator and whether they are resisted (do not alter the operation of the PVIS) or not (cause an abrupt stop of the FCs). Since the monitoring system of the PVIS under study only collected data every minute, it was not possible to obtain these indices in the present work.
The second processing step consisted of obtaining the ideal PVIS behavior map from the available operating conditions data (in-plane irradiance and cell temperature). The behavior map shows what time each FC should be started and how long it should be on, as well as the number of FCs that should be on simultaneously at each moment. This ideal map can be compared with the real map of the PVIS obtained from the production data. The actual map differs from the ideal for several reasons: it is affected by controlled stops not predictable from operating conditions and by abrupt stops of the FCs; it is altered by the existing water level in the intermediate tank (pumping from the borehole is prevented when the tank is full, and irrigation is not possible when it is empty); and it is highly dependent on the behavior of the end user.
Significant events were identified and classified:
  • The absence of data on operating conditions;
  • Time that is not part of the IP;
  • Events related to the irrigator’s use of the PVIS (such as the use of the PV/Diesel or Diesel modes or manual stops caused by the irrigator);
  • Events directly associated with the IS (such as a lack of water in the tank when the irrigator wants to irrigate or a full tank).
The event information (type and time at which they begin and end) was used, together with the stop information and the behavior maps (the ideal and actual ones), to calculate the utilization ratios and the PR.
When processing the data, a PV generator power equal to the measured actual power (150.3 kWp) was considered. Since the monitoring system does not record data from the pivot FC, the FC efficiency and the consumption of the motors that move the pivots were also measured (92.0% and 4.5 kW, respectively), considering an average PDC for the pivot FC of 4.5 kW whenever the irrigation FC was on.

3. Results

This study analyzed the data collected and the behavior of the PVIS between May 2019 and August 2022. During this time interval, the IP of each season was the same, starting on March 15 of each year and ending on October 15. However, since 2019, data were only available from the end of April, and in order to analyze and compare full-year data, each year under study was determined to start in May and end in April of the following year. Thus, the data presented below show the results for three full years of PVIS operation: from May 2019 to April 2020 (the first year), from May 2020 to April 2021 (the second year), and from May 2021 to April 2022 (the third year).

3.1. Number of Stops

FC stops are due to operating conditions (when irradiance drops below the minimum necessary threshold, the FC stops), IS limitations (if the intermediate tank is empty, the irrigation FC stops, and if it is full, the pumping FC stops), direct irrigator actions (the irrigator stops a FC to change the irrigation program, because he does not want to continue irrigating, or for any other reason), and control instabilities (caused, for example, by abrupt variations in available power due to passing clouds).
Table 1, Table 2 and Table 3 show the total number of abrupt and controlled stops per month and per day for each year, considering only days for which information is available and in which the FCs have been working. In all tables, FC 1 refers to the irrigation FC and FC 2 refers to the pumping FC. Pivot FC stops are not shown in the tables because the pivot FC was not monitored. In any case, since the pivot FC is always on during irrigation, it is started and stopped together with the irrigation FC, both having the same number of stops.
The number of days for which the data were available and the FCs were active in each month reflected that the period from mid-October to mid-March did not belong to the IP. However, during the third year of study, an activity increase can be seen in that period. Single days were used to fill the intermediate tank or for occasional irrigation. The low number of operating days in some months of the IP (e.g., August and September 2019) is also striking. This was due to a failure in the monitoring system, which was blocked and stopped storing information.
Table 1, Table 2 and Table 3 show that the total number of stops per day and per FC remained stable throughout the three years of PVIS operation. During the first year, the irrigation FC stopped an average of 3.62 times per day (3.29 + 0.33), 3.49 per day (3.26 + 0.23) during the second year, and 3.4 times in the third year (3.15 + 0.25). This represents a reduction in the total number of stops per day of 6.1% from the first year to the third. Regarding the pumping FC, the first year it stopped an average of 5.92 times per day (5.45 + 0.47), the second year 6.33 (5.9 + 0.43), and the third year 6.25 (6 + 0.25). This represents an increase in the number of stops per day of 5.6% between the first year and the last. The number of stops for the pumping FC was higher than that for the irrigation FC. This is because the PLC gives priority to the irrigation FC over the pumping FC whenever the irrigator wants to irrigate, so when irradiance decreases, the first FC to stop is the pumping FC. The percentage of abrupt stops in the pumping FC (7.9% the first year, 6.8% the second, and 4.0% the third) decreased over time. The percentage of abrupt stops in the irrigation FC (9.0%, 6.7%, and 7.5%, respectively) was of the same order of magnitude as in the pumping FC, with no clear trend in its evolution over time.

3.2. Performance Ratio

Table 4, Table 5 and Table 6 show the experimental monthly values of the performance indices.
The PRPV values (80.9% for the whole first year) were slightly below the PR values expected for grid-connected PV systems.
URIP was 100% from May to September and in April, lower than 100% in October, and 0% from November to January, resulting in a yearly value of 87.9%. It is striking that the March 2020 URIP was 100% considering that half of that month did not belong to the IP. It would have been reasonable to expect a lower value, close to 50%, in line with the values of days of operation of the FCs indicated in Table 5 (13 days for the irrigation FC and 16 for the pumping FC). The 100% value was due to the failure of the monitoring system from February 12 to March 16 and the exclusion of this interval from the study; we only analyzed the days between March 16 and 31, all of which were part of the IP.
The URPVIS first year value was 75.9%. Compared to those reported by [38] for PVIS pumping to a water pool (75.6% and 85.2%), the obtained value was similar to the first and lower than the second. It is reasonable to expect a lower URPVIS for a constant flow and constant-pressure PVIS than for a PVIS pumping to a water pool, in which the flow of pumped water can be adjusted to the available PV power. In constant-pressure and constant flow PVIS, power consumption is also constant, and the FC does not start until the irradiance reaches a threshold that allows the required PV power to be generated. The PV power that could be generated at all times of the day when the irradiance is below this threshold is lost. Similarly, the power that could be generated when the irradiance is above the threshold is lost because the PVIS cannot consume more power than necessary to achieve the pressure required by the pivots. In addition, the small size of the intermediate water tank also decreased URPVIS as the irrigation FC stopped when the tank was empty, and the borehole FC stopped when the tank was full.
The UREF value (92.3%) was smaller than expected (close to 100%). The possibility of using the diesel or PV/diesel modes and the water needs of the crop led the irrigator to use the diesel mode at night, at times of low irradiance, and when the intermediate tank was empty. The delay in switching to PV mode when the irradiance allowed it or when there was enough water in the tank to keep on irrigating caused the UREF to worsen. This effect was increased by the long stops of the PVIS when the irrigator changed the irrigation program.
The PR value was close to 50% (49.8%) due to the combined effect of all the previous indices, but especially URIP (highly dependent on the crop), URPVIS, and UREF.
The values obtained for the second and third years did not differ radically from those of the first year. The PR value for the second year (49.0%) was smaller than the 49.8% of the first year, mainly because of the decrease in the URIP due to proper accounting of the month of March. If this month had been correctly accounted for in the first year, the final PR value would have been even lower than the 49.0% of the second year (assuming for the first year the same total URIP value as the second year, 84.7%, the total PR would have been 48.0%). On the other hand, the PR improved for the third year (53.2%). Although the PRPV, which measures the quality of the PV system itself, decreased with respect to the first year, an improvement was observed for the rest of the indices. This improvement was caused by a longer IP (an increased usage in February), an improved use of the intermediate water tank, and, in general, a better use of the PVIS by the irrigator. The evolution of the indices over the three years can be seen in Table 7.

4. Discussion

Stand-alone high-power PV irrigation systems with no batteries are relatively new, and there are not enough data available in the literature on their expected experimental performance values. It is useful to establish the thresholds required in the quality control procedures associated with contractual frameworks for the sale and installation of this type of PVIS. This section discusses the experimental results of the different performance indices found in this analysis.

4.1. Expected PR Values for High-Power PVIS Combining Pumping to an Intermediate Tank and Direct Pumping to an IS Based on Pivots

This study began with the intuition that the PR of constant-pressure PVIS should be lower than that for PVIS pumping to a water pool. PVIS pumping to a water pool work at variable frequency. They adapt the FC output frequency to the available PV power, varying the pumped flow at each moment. When the available PV power is low, the FC output frequency is low. The operating frequency and the pumped flow rate increase as the available PV power increases up to the maximum allowed by the pump, thus working in a range of frequencies. In contrast, direct pumping PVIS operates at a constant flow and pressure. To provide that flow and pressure, the motor pump has to work at a certain frequency, consuming a specific amount of power. The FC does not start until the irradiance reaches a threshold that allows the required PV power to be generated. The power that could be generated at all times of the day when the irradiance is below this threshold is lost. Similarly, some of the PV power that could be generated when the irradiance is above the threshold is lost because the PVIS cannot consume more power than necessary to achieve the pressure required by the pivots. The system works at a single frequency instead of several frequencies and consumes a certain power instead of a range of powers, thus making less use of the available PV power. This is a feature associated with the PVIS design. Therefore, when factorizing the PR, a decrease in the URPVIS (the utilization ratio that takes into account losses of this type) should be observed.
The PVIS under study was not strictly a constant-pressure IS. It combined three FCs. The irrigation FC was typical of a constant-pressure IS, the pumping FC was typical of a PVIS pumping to a water pool, and the pivots FC had constant consumption whenever irrigation was taking place. This variety of FCs and their different power ratings mitigated the reduction in URPVIS, but it should still be observed.

4.1.1. URPVIS Values

The results showed annual URPVIS values between 75.9% and 81.2%, which represents a decrease between 4.7% and 10.9% with respect to the values reported by [38] for Villena PVIS pumping to a water pool (Aldeanueva’s value was not used as a reference because it was affected by the oversizing of the PV generator, which caused a reduction in the URPVIS). This decrease was in line with what was expected prior to the start of the study.
The data also showed an improvement in URPVIS over time (from 75.9% to 78.0% and 81.2%) that can be explained by the improvement in the use of the intermediate tank. The irrigator used the diesel mode at night and at times of low irradiance and the PV/Diesel mode during the day when the tank was empty, reducing the full/empty tank time during the day. The other factors that affected URPVIS did not change: the power of the PV generator, the size of the intermediate tank, the ratio of PV peak power to PV power required for irrigation, the irrigated land, the irrigation programs, and the pressures required by the pivots. The number of controlled stops per day due to low levels of irradiance (and the time the PVIS remained stopped for safety after each stop) does not explain the improvement in URPVIS either, as it did not change over the three years (8.7 controlled stops per day the first year, 9.16 the second, and 9.15 the third).
The relationship between the improvement of URPVIS and the reduction of full/empty tank times can be seen in Table 8, which shows that when the number of minutes per day that the tank is full or empty increases, URPVIS decreases. The table shows no relationship between the evolution of URPVIS and the number of controlled stops. The months of July and August were chosen as the months with the highest URPVIS. The high temperatures of these months resulted in lower production and, therefore, lower limitations due to excess power in the constant-pressure PVIS.
Even though the times in which the tank was full or empty were counted together, it is important to note that the impact of a full tank is not the same as that of an empty tank. Moreover, the impact also depends on the corrective action taken by the irrigator: using the diesel mode, the PV/diesel mode, or leaving the PV on.
The above data suggested that, once the learning curve of the use of the PVIS has been traversed, during which the URPVIS improved due to the use of the intermediate tank, this index will not improve any further. Therefore, the expected URPVIS losses in a constant-pressure PVIS, such as the one studied, with respect to a PVIS pumping to a water pool can be quantified at around 5%, and it is reasonable to expect URPVIS values of 80% for this type of system.

4.1.2. PRPV Values

The PRPV annual values (80.9%, 79.0%, and 79.4%) were slightly lower than the PR values expected for grid-connected PV systems. Temperature losses do not explain the difference. PRPV values under standard test conditions (89.3%, 87.1%, and 87.1%, respectively) were still low compared to those expected for grid-connected PV systems (and lower than the 95.7% reported by [38] for the Aldeanueva PVIS). Abrupt stops introduced by control instabilities associated with the IS do not explain the existing difference either, especially if we take into account that the number of abrupt stops detected may be lower than the real number. The data showed that it is reasonable to expect PRPV values over 80.0%.

4.1.3. URIP Values

URIP is very dependent on the crop and climate conditions where the PVIS is located. In a direct pumping PVIS, these two factors determine the irrigation period. When pumping to a water pool or an intermediate tank, the IP can be extended. The additional extension depends on the capacity of the tank. In the PVIS under study, the IP started on March 15 and ended on October 15, and in the third year, it was extended a few days more. The 1000 m3 intermediate tank did not allow the IP to be extended any further. Under these conditions, it is reasonable to assume that the URIP will remain around 85%.

4.1.4. UREF Values

UREF values improved every year (from 92.3% to 93.8% and 94.7%), which indicates a better use of the PVIS by the irrigator. The time the system was down as a result of controlled stops caused by the irrigator was also reduced. As an example, the number of minutes it was down per day in July and August (considering only the interval between 7:00 and 19:00 UTC) was reduced by 21.6% from the first to the second year and by 81.4% from the first to the third year, and the time it was working in diesel or PV/diesel mode was reduced by 45.7% and 29.8%, respectively. A proper use of the PVIS by the irrigator (not using the diesel or PV/diesel modes when there is enough irradiation to use the PV mode, avoiding manual shutdowns, PV irrigation schedule centered at midday, planning of maintenance tasks on cloudy days or at night, management of water consumption) would lead to values very close to 100%, as seen in our results.
PRPV, URIP, URPVIS, and UREF determine the PR values. The PR values obtained experimentally were between 49.0 and 53.2%. The expected values for each index (PRPV >= 80%, URIP >= 85%, URPVIS >= 80%, and UREF = 100%) suggest that it is reasonable to expect PR values around 55% in high-power constant-pressure PVIS.

4.2. Number of Abrupt Stops

Since abrupt stops can cause water hammers and AC over-voltages that seriously threaten the reliability of both the hydraulic and electric components of the PVIS, a reduced number of abrupt stops reduces the risks.
The current study was not decisive in relation to the maximum number of abrupt stops that can be expected from a PVIS with these characteristics or the relationship between the number of abrupt and controlled stops that is advisable. The difficulties encountered in identifying the type of stop prevented this. Stops listed in the tables as abrupt for each inverter were indeed abrupt, but there is no certainty that stops listed as controlled were actually all controlled. A detailed analysis of the data suggested that the percentage of abrupt stops could be higher than that shown in the tables. Multiple FC stops occur in typical passing cloud situations (irradiance drops abruptly for a short interval and then recovers). In these situations, the FC should stop in a controlled way if the irradiance remains for more than one minute below a given threshold, and it should remain on in any other case. Due to the characteristics of the monitoring system, which records data only every minute, it was not possible to know the exact duration of the irradiance drop or whether the drop was sustained for a minute or not. The high number of FC stops in passing cloud circumstances lead us to suspect that not all of them were due to irradiance drops lasting more than one minute. Therefore, some of the FC stops may have been due to control instabilities and have been abrupt, although the monitoring system did not always record them. To confirm the suspicion that the number of abrupt stops were higher than that recorded, a monitoring system is needed that records data every second or records the abrupt stop status accurately. If a high number of abrupt stops was confirmed, the PVIS would have to be tuned to improve its performance.

5. Conclusions

Stand-alone battery-free, high-power PV irrigation systems are emerging as an alternative to high-power diesel-based or grid-connected irrigation systems. As a recent innovation, there is not enough experimental data available on their performance. A few performance data are available for PVIS pumping to a water pool, but no data are available for constant-pressure PVIS, although their design characteristics suggest a reduction in PR. This paper is a contribution to the experimental performance data of a constant-pressure center-pivot PVIS and, thus, to the expected values for other similar systems.
To assess the PVIS performance, the traditional PR was factorized into four factors: PRPV, URIP, URPVIS, and UREF. PRPV evaluates the performance quality of the PV system itself. URIP, URPVIS, and UREF measure the effect of the crop irrigation period, losses due to the IS design, and losses due to user behavior, respectively. In order to calculate these indexes, the FC stops were identified and classified as controlled, abrupt, automatic, or caused by the irrigator. Secondly, the ideal behavior map of the PVIS was obtained from the available data on operating conditions (irradiance and temperature) and the real map of the plant, which was obtained from the production data. Next, significant events were identified and classified (absence of operating conditions data, duration of the irrigation period, use of the PV/diesel or diesel modes, when the irrigator manually stops the PVIS, and other events such as a full or empty tank). Finally, event and stop information and PVIS operation maps (the ideal and actual ones) were processed to calculate the utilization ratios and the PR.
The results showed annual URPVIS values between 75.9% and 81.2%, annual PRPV values between 79.0% and 80.9%, annual URIP values between 84.7% and 87.9%, annual UREF values between 92.3% and 94.7%, and PR values between 49.0% and 53.2%.
The two indices that had the greatest impact on PR were URPVIS and PRPV. The former is intrinsic to the PVIS design, and the latter is conditioned by the quality of the PV system itself. The most important factor influencing the URPVIS is the fact that the PVIS works at constant-pressure. Working at constant-pressure means that the FC does not start until the available PV power reaches the power needed to operate the pump at the pressure required by the pivots, and that the additional PV power that the generator could supply if conditions improve is wasted. The impact of this feature on URPVIS was a 5% decrease over PVIS pumping to a water pool. The second element that most affects URPVIS is related to the size of the tank and the irrigator’s management of it. This factor can be improved with proper training of the irrigator.
Relevant conclusions can be drawn from the results regarding the performance that can be expected: The expected PR in a good-quality constant-pressure PVIS is around 55%. The expected values for the different factors are PRPV >= 80%, similar to those expected in grid-connected PV systems; URIP >= 85%; URPVIS >= 80%; and UREF ≈ 100% if the end user makes appropriate use of the PVIS. It is necessary to confirm these expected values with experimental measurements in other high-power constant-pressure PVIS, but these preliminary results may help to establish the technical thresholds to ensure the technical quality of these systems in the context of quality control procedures associated with contracts for the sale and installation of this type of system.

Author Contributions

Conceptualization, J.I.H. and L.N.; data curation, J.I.H. and M.C.-C.; formal analysis, J.I.H.; funding acquisition, L.N.; investigation, J.I.H., R.H.A. and L.N.; methodology, R.H.A. and L.N.; project administration, L.N.; resources, J.I.H., M.C.-C. and L.N.; software, J.I.H. and M.C.-C.; supervision, L.N.; validation, J.I.H.; visualization, J.I.H.; writing—original draft, J.I.H.; writing—review and editing, J.I.H., R.H.A., M.C.-C. and L.N. All authors have read and agreed to the published version of the manuscript.

Funding

This research was made possible thanks to funding from the European Union’s Horizon 2020 research and innovation program for the SOLAQUA project under grant agreement Nº 952879 and thanks to the European Union’s Horizon 2020 research and innovation program to SERENDI-PV project under grant agreement Nº 953016.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study, in the collection, analysis, or interpretation of data, in the writing of the manuscript, or in the decision to publish the results.

References

  1. Palz, W. The French Connection: The rise of the PV water pump. Refocus 2001, 2, 46–47. [Google Scholar] [CrossRef]
  2. Barlow, R.; McNelis, B.; Derrick, A. Solar pumping: An introduction and update on the technology, performance, costs, and economics. World Bank Tech. Pap. 1993, 168, 12. [Google Scholar]
  3. Abella, M.A.; Lorenzo, E.; Chenlo, F. PV water pumping systems based on standard frequency converters. Prog. Photovolt. Res. Appl. 2003, 11, 179–191. [Google Scholar] [CrossRef]
  4. Sontake, V.C.; Kalamkar, V.R. Solar photovoltaic water pumping system—A comprehensive review. Renew. Sustain. Energy Rev. 2016, 59, 1038–1067. [Google Scholar] [CrossRef]
  5. Chabour, H.E.; Pardo, M.A.; Riquelme, A. Economic assessment of converting a pressurised water distribution network into an off-grid system supplied with solar photovoltaic energy. Clean Technol. Environ. Policy 2022, 24, 1823–1835. [Google Scholar] [CrossRef]
  6. Zegait, R.; Bentraia, M.R.; Bensaha, H.; Azlaoui, M. Comparative Study of a Pumping System Using Conventional and Photovoltaic Power in the Algerian Sahara (Application to Pastoral Wells). Int. J. Eng. Res. Afr. 2022, 60, 63–74. [Google Scholar] [CrossRef]
  7. Skibko, Z.; Romaniuk, W.; Borusiewicz, A.; Derehajło, S. Electricity supply to irrigation systems for crops away from urban areas. J. Water Land Dev. 2022, 53, 73–79. [Google Scholar] [CrossRef]
  8. Saady, I.; Karim, M.; Bossoufi, B.; Motahhir, S.; Majout, B.; Salime, H.; Laabidine, N.Z. Study of a Photovoltaic Pumping System Application for Irrigation the Palm in Beni Mellal City. In Lecture Notes in Networks and Systems; Springer: Cham, Switzerland, 2022; Volume 454. [Google Scholar] [CrossRef]
  9. Zavala, V.; López-Luque, R.; Reca, J.; Martínez, J.; Lao, M. Optimal management of a multisector standalone direct pumping photovoltaic irrigation system. Appl. Energy 2019, 260, 114261. [Google Scholar] [CrossRef]
  10. Miran, S.; Tamoor, M.; Kiren, T.; Raza, F.; Hussain, M.I.; Kim, J.-T. Optimization of Standalone Photovoltaic Drip Irrigation System: A Simulation Study. Sustainability 2022, 14, 8515. [Google Scholar] [CrossRef]
  11. Kumar, L.A.; Lakshmiprasad, C.N.; Ramaraj, G.; Sivasurya, G. Design, simulation of different configurations and life-cycle cost analysis of solar photovoltaic–water-pumping system for agriculture applications: Use cases and implementation issues. Clean Energy 2022, 6, 335–352. [Google Scholar] [CrossRef]
  12. Ledesma, J.R.; Almeida, R.H.; Narvarte, L. Modeling and Simulation of Multipumping Photovoltaic Irrigation Systems. Sustainability 2022, 14, 9318. [Google Scholar] [CrossRef]
  13. Gasque, M.; González-Altozano, P.; Gutiérrez-Colomer, R.P.; García-Marí, E. Optimisation of the distribution of power from a photovoltaic generator between two pumps working in parallel. Sol. Energy 2020, 198, 324–334. [Google Scholar] [CrossRef]
  14. Farrar, L.W.; Bahaj, A.S.; James, P.; Anwar, A.; Amdar, N. Floating solar PV to reduce water evaporation in water stressed regions and powering water pumping: Case study Jordan. Energy Convers. Manag. 2022, 260, 115598. [Google Scholar] [CrossRef]
  15. Calero-Lara, M.; López-Luque, R.; Casares, F.J. Methodological Advances in the Design of Photovoltaic Irrigation. Agronomy 2021, 11, 2313. [Google Scholar] [CrossRef]
  16. Guillén-Arenas, F.J.; Fernández-Ramos, J.; Narvarte, L. A New Strategy for PI Tuning in Photovoltaic Irrigation Systems Based on Simulation of System Voltage Fluctuations Due to Passing Clouds. Energies 2022, 15, 7191. [Google Scholar] [CrossRef]
  17. Cervera-Gascó, J.; Perea, R.G.; Montero, J.; Moreno, M.A. Prediction Model of Photovoltaic Power in Solar Pumping Systems Based on Artificial Intelligence. Agronomy 2022, 12, 693. [Google Scholar] [CrossRef]
  18. Fara, L.; Craciunescu, D.; Fara, S. Numerical Modelling and Digitalization Analysis for a Photovoltaic Pumping System Placed in the South of Romania. Energies 2021, 14, 2778. [Google Scholar] [CrossRef]
  19. Boukebbous, S.E.; Benbaha, N.; Bouchakour, A.; Ammar, H.; Bouhoun, S.; Kerdoun, D. Experimental performance assessment of photovoltaic water pumping system for agricultural irrigation in semi-arid environment of Sebseb—Ghardaia, Algeria. Int. J. Energy Environ. Eng. 2022, 13, 979–994. [Google Scholar] [CrossRef]
  20. Santra, P. Performance evaluation of solar PV pumping system for providing irrigation through micro-irrigation techniques using surface water resources in hot arid region of India. Agric. Water Manag. 2021, 245, 106554. [Google Scholar] [CrossRef]
  21. Zhao, B.; Ren, Y.; Gao, D.; Xu, L. Performance ratio prediction of photovoltaic pumping system based on grey clustering and second curvelet neural network. Energy 2019, 171, 360–371. [Google Scholar] [CrossRef]
  22. Wurthmann, K.A. Designing photovoltaic arrays for groundwater pumping for remote agriculture using synthetically generated daily rainfall and irrigation needs. J. Eng. Des. Technol. 2021. ahead-of-print. [Google Scholar] [CrossRef]
  23. García, A.M.; Perea, R.G.; Poyato, E.C.; Barrios, P.M.; Díaz, J.R. Comprehensive sizing methodology of smart photovoltaic irrigation systems. Agric. Water Manag. 2020, 229, 105888. [Google Scholar] [CrossRef]
  24. Cervera-Gascó, J.; Montero, J.; del Castillo, A.; Tarjuelo, J.M.; Moreno, M.A. EVASOR, an Integrated Model to Manage Complex Irrigation Systems Energized by Photovoltaic Generators. Agronomy 2020, 10, 331. [Google Scholar] [CrossRef]
  25. Monís, J.I.; López-Luque, R.; Reca, J.; Martínez, J. Multistage Bounded Evolutionary Algorithm to Optimize the Design of Sustainable Photovoltaic (PV) Pumping Irrigation Systems with Storage. Sustainability 2020, 12, 1026. [Google Scholar] [CrossRef]
  26. Mindú, A.J.; Capece, J.A.; Araújo, R.E.; Oliveira, A.C. Feasibility of Utilizing Photovoltaics for Irrigation Purposes in Moamba, Mozambique. Sustainability 2021, 13, 10998. [Google Scholar] [CrossRef]
  27. Ghasemi-Mobtaker, H.; Mostashari-Rad, F.; Saber, Z.; Chau, K.-W.; Nabavi-Pelesaraei, A. Application of photovoltaic system to modify energy use, environmental damages and cumulative exergy demand of two irrigation systems—A case study: Barley production of Iran. Renew. Energy 2020, 160, 1316–1334. [Google Scholar] [CrossRef]
  28. Raza, F.; Tamoor, M.; Miran, S.; Arif, W.; Kiren, T.; Amjad, W.; Hussain, M.I.; Lee, G.-H. The Socio-Economic Impact of Using Photovoltaic (PV) Energy for High-Efficiency Irrigation Systems: A Case Study. Energies 2022, 15, 1198. [Google Scholar] [CrossRef]
  29. Pombo-Romero, J.; Rúas-Barrosa, O. A Blockchain-Based Financial Instrument for the Decarbonization of Irrigated Agriculture. Sustainability 2022, 14, 8848. [Google Scholar] [CrossRef]
  30. Lefore, N.; Closas, A.; Schmitter, P. Solar for all: A framework to deliver inclusive and environmentally sustainable solar irrigation for smallholder agriculture. Energy Policy 2021, 154, 112313. [Google Scholar] [CrossRef]
  31. Chazarra-Zapata, J.; Molina-Martínez, J.M.; de la Cruz, F.-J.P.; Parras-Burgos, D.; Canales, A.R. How to Reduce the Carbon Footprint of an Irrigation Community in the South-East of Spain by Use of Solar Energy. Energies 2020, 13, 2848. [Google Scholar] [CrossRef]
  32. Maslowaten. Maslowaten H2020 Project. 2016. Available online: http://maslowaten.eu/ (accessed on 1 April 2021).
  33. Fernández-Ramos, J.; Narvarte-Fernández, L.; Poza-Saura, F. Improvement of photovoltaic pumping systems based on standard frequency converters by means of programmable logic controllers. Sol. Energy 2010, 84, 101–109. [Google Scholar] [CrossRef]
  34. Almeida, R.H.; Carrêlo, I.B.; Lorenzo, E.; Narvarte, L.; Fernández-Ramos, J.; Martínez-Moreno, F.; Carrasco, L.M. Development and Test of Solutions to Enlarge the Power of PV Irrigation and Application to a 140 kW PV-Diesel Representative Case. Energies 2018, 11, 3538. [Google Scholar] [CrossRef]
  35. Todde, G.; Murgia, L.; Deligios, P.A.; Hogan, R.; Carrelo, I.; Moreira, M.; Pazzona, A.; Ledda, L.; Narvarte, L. Energy and environmental performances of hybrid photovoltaic irrigation systems in Mediterranean intensive and super-intensive olive orchards. Sci. Total. Environ. 2019, 651, 2514–2523. [Google Scholar] [CrossRef]
  36. Das, M.; Mandal, R. A comparative performance analysis of direct, with battery, supercapacitor, and battery-supercapacitor enabled photovoltaic water pumping systems using centrifugal pump. Sol. Energy 2018, 171, 302–309. [Google Scholar] [CrossRef]
  37. Luque, A.; Hegedus, S. Handbook of Photovoltaic Science and Engineering, 2nd ed.; Johm Wiley & Sons: Chichester, UK, 2011. [Google Scholar]
  38. Herraiz, J.I.; Fernández-Ramos, J.; Almeida, R.H.; Báguena, E.M.; Castillo-Cagigal, M.; Narvarte, L. On the tuning and performance of Stand-Alone Large-Power PV irrigation systems. Energy Convers. Manag. 2022, 13, 100175. [Google Scholar] [CrossRef]
  39. Livera, A.; Theristis, M.; Koumpli, E.; Theocharides, S.; Makrides, G.; Sutterlueti, J.; Stein, J.S.; Georghiou, G.E. Data processing and quality verification for improved photovoltaic performance and reliability analytics. Prog. Photovolt. Res. Appl. 2021, 29, 143–158. [Google Scholar] [CrossRef]
  40. Koumpli, E. Impact of Data Quality on Photovoltaic (PV) Performance Assessment. 2017. Available online: https://repository.lboro.ac.uk/articles/thesis/Impact_of_data_quality_on_photovoltaic_PV_performance_assessment/9534902 (accessed on 12 February 2023).
  41. Lindig, S.; Louwen, A.; Moser, D.; Topic, M. Outdoor PV System Monitoring—Input Data Quality, Data Imputation and Filtering Approaches. Energies 2020, 13, 5099. [Google Scholar] [CrossRef]
  42. IEC. IEC 61724-2 TS: Photovoltaic System Performance—Part 2: Capacity Evaluation Method; IEC: Vienna, Austria, 2016. [Google Scholar]
Figure 1. Pre-existing IS configuration: The diesel generator feeds the borehole, irrigation pumps, and the pivots.
Figure 1. Pre-existing IS configuration: The diesel generator feeds the borehole, irrigation pumps, and the pivots.
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Figure 2. PVIS configuration: A PV generator, three FCs (all in green), and a PLC were added to the pre-existing configuration (diesel generator, two FCs in red, and two motor-pumps).
Figure 2. PVIS configuration: A PV generator, three FCs (all in green), and a PLC were added to the pre-existing configuration (diesel generator, two FCs in red, and two motor-pumps).
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Figure 3. Available PV power thresholds with hysteresis for start and stop of the FCs, indicating when start and stop signals were sent (1—irrigation and pivots FCs start signal, 2—pumping FC start signal, 3—pumping FC stop signal, and 4—irrigation and pivots FCs stop signal).
Figure 3. Available PV power thresholds with hysteresis for start and stop of the FCs, indicating when start and stop signals were sent (1—irrigation and pivots FCs start signal, 2—pumping FC start signal, 3—pumping FC stop signal, and 4—irrigation and pivots FCs stop signal).
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Figure 4. Aerial view of the PVIS in Alaejos.
Figure 4. Aerial view of the PVIS in Alaejos.
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Figure 5. Graphical representation of: (a) G d t (blue area); (b) I P G d t (orange area), where the irrigation period starts at 8:00 and ends after 23:00; (c) G u s e f u l d t (light green area), where the PVIS could be on from 9:00 to 19:45; and (d) G u s e d d t (dark green area), where the irrigator decides to start the PVIS at 14:00.
Figure 5. Graphical representation of: (a) G d t (blue area); (b) I P G d t (orange area), where the irrigation period starts at 8:00 and ends after 23:00; (c) G u s e f u l d t (light green area), where the PVIS could be on from 9:00 to 19:45; and (d) G u s e d d t (dark green area), where the irrigator decides to start the PVIS at 14:00.
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Table 1. Number of stops of each FC during the first year.
Table 1. Number of stops of each FC during the first year.
YearMonthDays
FC 1/FC 2
Controlled Stops FC 1Abrupt Stops FC 1Controlled Stops FC 2Abrupt Stops FC 2
201905311321319230
0630114819416
0731106512329
0816/15454893
09205431111
1017/184712951
1100000
1200000
20200100000
0200000
0313/16302740
0417/114810560
Total175/172576 (91.0%)57 (9.0%)938 (92.1%)80 (7.9%)
Total per day-3.290.335.450.47
Table 2. Number of stops of each FC during the second year.
Table 2. Number of stops of each FC during the second year.
YearMonthDays
FC 1/FC 2
Controlled Stops FC 1Abrupt Stops FC 1Controlled Stops FC 2Abrupt
Stops FC 2
2020052790115412
0630129628928
072971911716
0831931817117
0922/194011779
1016/186511240
1100000
1200000
2021010/60044
0200000
0316/17560612
0430/2911112181
Total201/206655 (93.3%)47 (6.7%)1215 (93.2%)89 (6.8%)
Total per day-3.260.235.90.43
Table 3. Number of stops of each FC during the third year.
Table 3. Number of stops of each FC during the third year.
YearMonthDays
FC 1/FC 2
Controlled Stops FC 1Abrupt Stops FC 1Controlled Stops FC 2Abrupt
Stops FC 2
2021053110512556
0628/2798517214
0731105613311
0831761411012
092588112053
1024/289581610
114/11602811
120/400120
20220100000
02185361031
0312/142931030
0424/276341994
Total228/248719 (92.5%)58 (7.5%)1487 (96.0%)62 (4.0%)
Total per day-3.150.2560.25
Table 4. Experimental monthly values of the performance indices (%) for the first year.
Table 4. Experimental monthly values of the performance indices (%) for the first year.
YearMonth PRPVURIPURPVISUREFPR
201905 80.710083.792.762.6
0680.610080.894.061.2
0777.910087.992.863.6
0879.710080.395.060.8
0986.410082.293.166.1
1086.375.981.397.151.7
11-0--0.0
12-0--0.0
202001-0--0.0
02-0--0.0
0384.110060.692.046.8
0478.110027.062.613.2
Total80.987.975.992.349.8
Table 5. Experimental monthly values of the performance indices (%) for the second year.
Table 5. Experimental monthly values of the performance indices (%) for the second year.
YearMonth PRPVURIPURPVISUREFPR
202005 79.910076.092.556.2
0678.810082.597.763.5
0775.410079.295.256.8
0877.110084.895.962.7
0979.210061.884.141.2
1082.580.976.593.147.5
11-0--0.0
12-0--0.0
20210189.29.292.71007.6
02-0--0.0
0380.066.180.087.637.1
0483.510080.196.564.5
Total79.084.778.093.849.0
Table 6. Experimental monthly values of the performance indices (%) for the third year.
Table 6. Experimental monthly values of the performance indices (%) for the third year.
YearMonth PRPVURIPURPVISUREFPR
202105 81.410081.295.763.3
0680.210081.892.260.5
0780.410088.698.169.9
0879.710092.897.572.1
0982.210064.895.350.8
1082.896.878.698.261.9
1184.217.792.996.113.3
1272.61.372.81000.7
20220194.10.751.41000.3
0283.363.389.296.945.6
0386.282.256.860.624.4
0467.610080.395.651.9
Total79.487.281.294.753.2
Table 7. Experimental annual values of the performance indices (%).
Table 7. Experimental annual values of the performance indices (%).
PeriodPRPVURIPURPVISUREFPR
2019-05 to 2020-04 80.987.975.992.349.8
2020-05 to 2021-0479.084.778.093.849.0
2021-05 to 2022-0479.487.281.294.753.2
Table 8. Monthly URPVIS, time the intermediate tank remains empty or full (in minutes per day, considering only the interval between 7:00 and 19:00 UTC), and the number of controlled stops per day for the months of July and August over the three years.
Table 8. Monthly URPVIS, time the intermediate tank remains empty or full (in minutes per day, considering only the interval between 7:00 and 19:00 UTC), and the number of controlled stops per day for the months of July and August over the three years.
URPVIS (%)92.8 88.687.984.880.379.2
Full/empty-tank time (minutes per day)21253071101134
Controlled stops (per day)6.010.37.48.58.96.5
Month2021-082021-072018-072020-082019-082020-07
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MDPI and ACS Style

Herraiz, J.I.; Almeida, R.H.; Castillo-Cagigal, M.; Narvarte, L. Experimental Performance Evaluation of a PV-Powered Center-Pivot Irrigation System for a Three-Year Operation Period. Energies 2023, 16, 3654. https://doi.org/10.3390/en16093654

AMA Style

Herraiz JI, Almeida RH, Castillo-Cagigal M, Narvarte L. Experimental Performance Evaluation of a PV-Powered Center-Pivot Irrigation System for a Three-Year Operation Period. Energies. 2023; 16(9):3654. https://doi.org/10.3390/en16093654

Chicago/Turabian Style

Herraiz, Juan Ignacio, Rita Hogan Almeida, Manuel Castillo-Cagigal, and Luis Narvarte. 2023. "Experimental Performance Evaluation of a PV-Powered Center-Pivot Irrigation System for a Three-Year Operation Period" Energies 16, no. 9: 3654. https://doi.org/10.3390/en16093654

APA Style

Herraiz, J. I., Almeida, R. H., Castillo-Cagigal, M., & Narvarte, L. (2023). Experimental Performance Evaluation of a PV-Powered Center-Pivot Irrigation System for a Three-Year Operation Period. Energies, 16(9), 3654. https://doi.org/10.3390/en16093654

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