To analyse the performance of a PV installation, the plane irradiance, cell temperature and environmental conditions are needed to enable the I-V curves to be measured with accuracy. The Fluke Solmetric PVA 1500 PV Analyser and I-V Curve Tracer is ideal for delivering reliable results.
For accurate array performance measurements, mount the wireless irradiance sensor in the plane of the array and make sure that the sensor’s spectral response matches that of the PV modules. This sensor also measures backside temperature and module tilt.
Optimal performance tests for PV-installations must be conducted under stable weather conditions with irradiance above 700 W/m². This is particularly crucial when establishing a performance baseline at commissioning or recommissioning and for relevant troubleshooting. The standard test condition irradiance is 1 000 W/m2, and the closer the field test conditions are to these standard test conditions, the more accurate the interpretation of I-V curves will be. Good test conditions will most likely occur during the four-hour window around solar noon.
Irradiance measurement errors can significantly affect photovoltaic performance testing. For instance, a small error margin in irradiance can overshadow the accuracy of even high-quality I-V curve tracers like the Fluke Solmetric PVA-1500. Fast-moving clouds near the sun and high-elevation cirrus clouds are particularly problematic.
One of the benefits of using I-V curve tracers for performance test measurements is that you can save critical environmental data along with the I-V data. This eliminates manual data entry errors that can cause trouble later, and minimises the opportunity for errors associated with rapid changes in test conditions.
Choice of sensors
True pyranometers are not a good choice for I-V curve testing, as they have a wide, flat spectral response that differs from that of crystalline and thin-film PV module technologies. Hand-held irradiance sensors are also not a good choice, as it can be challenging to orient them reliably and repeatedly in the plane of the array. Hand-held irradiance sensors may also have an angular response that differs substantially from PV modules in the field.
Angular response is significant early and late in the day and on days when cloud cover scatters a significant amount of sunlight. Under these test conditions, the array and sensor must have an equally wide sky view.
Irradiance sensors must not be influenced by strong optical reflections, as this can lead to inaccurate readings. If the irradiance sensor picks up significantly more reflected light than the PV modules under test, the model will over-predict the maximum current (Isc) and the module will appear to be underperforming. Under certain circumstances, sunlight reflected from metal surfaces can greatly exaggerate the irradiance reading. This can usually be remedied by changing the sensor mounting location.
Temperature measurements in PV system
While PV module performance is less sensitive to temperature variations than irradiance, it is still a significant factor. Light-gauge thermocouples are preferred for measuring cell temperature under varying conditions. Positioning the thermocouple correctly is vital for accurate readings. Since array and module edges tend to run cool, position the thermocouple between the corner and the centre of a module located away from the cooler array perimeter.
This practice aims to select a sensor attachment point that approximates the average backside temperature. The tip of the thermocouple must make good contact with the back of the PV module, as air gaps interrupt heat transfer, resulting in low-temperature readings. When moving the thermocouple between identical array sections, place it at the same relative location each time to avoid introducing artificial temperature shifts.
For product information on Fluke Solmetric PVA 1500 PV Analyser and I-V Curve Tracer, click here.
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