Low-Cost Electronics for Online I-V Tracing at Photovoltaic Module Level: Development of Two Strategies and Comparison between Them

José Ignacio Morales-Aragonés,María Del Carmen Alonso-García,Víctor Alonso-Gómez,Oscar Martínez,Luis Hernández-Callejo,Francisco José Sánchez-Pacheco,Sara Gallardo-Saavedra,Miguel Angel González,Miguel Angel Muñoz-García

doi:10.3390/electronics10060671

Abstract

The measurement of current–voltage (I-V) curves of single photovoltaic (PV) modules is at this moment the most powerful technique regarding the monitoring and diagnostics of PV plants, providing accurate information about the possible failures or degradation at the module level. Automating these measurements and allowing them to be made online is strongly desirable in order to conceive a systematic tracking of plant health. Currently, I-V tracers present some drawbacks, such as being only for the string level, working offline, or being expensive. Facing this situation, the authors have developed two different low-cost online I-V tracers at the individual module level, which could allow for a cost-affordable future development of a fully automated environment for the tracking of the plant status. The first system proposed implements a completely distributed strategy, since all the electronics required for the I-V measurement are located within each of the modules and can be executed without a power line interruption. The second one uses a mixed strategy, where some common electronics are moved from PV modules to the inverter or combiner box and need an automated very short disconnection of the modules string under measurement. Experiments show that both strategies allow the tracing of individual panel I-V curves and sending of the data afterwards in numerical form to a central host with a minimum influence on the power production and with a low-cost design due to the simplicity of the electronics. A comparison between both strategies is exposed, and their costs are compared with the previous systems proposed in the literature, obtaining cost reductions of over 80–90% compared with actual commercial traces.

Highlights

The annual global market for photovoltaic (PV) solar energy has increased considerably in recent years
With the module disconnected from the string for the commercial tester measurements, Under production with the prototype card connected to one module within the string, and the string connected to the inverter for distributed strategy, Over the whole string (11 modules in series) disconnected from the inverter for the mixed strategy
The main goal of our work regarding the low cost of the system and the simplicity of the electronics in order to make its commercial introduction feasible has been successfully accomplished

Summary

Introduction

The annual global market for photovoltaic (PV) solar energy has increased considerably in recent years. The total accumulated capacity has been increased by 25%, reaching the value of 5785 GW. This supposes a substantial growth if it is compared with the 15 GW of the previous decade. Self-consumption remained an important driver of the market for new systems distributed in some regions, and corporate purchases of PV solar energy expanded considerably, in the United States and Europe. In the year 2018, investment was made in a new, more efficient production capacity and additional advances in solar PV technology. At the end of 2018, at least 32 countries had an accumulated capacity of 1 GW or more. PV solar technology played a significant and growing role in the generation of electricity in several countries, including Honduras (12.1%), Italy, and Greece (both around 8.2%), and by the end of 2018, one in five Australian households generated at least part of their electricity with solar PV [1]

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