Modeling and estimating yield and efficiency of photovoltaic solar parks

Bizzarri, Federico; Brambilla, A.; Gruosso, Giambattista; Guardiani, Carlo; Sangiovanni-Vincentelli, A.; Gajani, G. Storti

doi:10.1109/icit.2013.6505763

Cited by 9 publications

(6 citation statements)

References 22 publications

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“…The idea is that the photovoltaic system and the rest of the system are executed in parallel in real time and the maximum power is monitored for irradiation variation in the real world and the extracted power is supplied to the DC bus to which storage element and the fixed load resistance are connected. The modeling of these systems are done in Simulink [9]. The modeled systems are compiled and deployed in NI myRIO's FPGA [10] for realtime simulation.…”

Section: The Memory Of the Real-time Digital Simulator (Rtds)mentioning

confidence: 99%

“…The mathematical model will be simulated in myRIO in real-time. FPGA IO's are used to The model will be implemented in MATLAB-Simulink [9] and translated in into C code with its internal C code generating tool using the NI VeriStand compilers which adds on to the MATLAB and it can generate the file ".SO" which defines our model with the libraries. NI VeriStand Engine has to be deployed in the RT target to make it compatible to run with the host computer.…”

Section: Real-time Simulation Architecturementioning

confidence: 99%

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Modelling of Photovoltaic Systems for Real-Time Hardware Simulation

Palahalli

Huo

Gruosso

2020

Lecture Notes in Electrical Engineering

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The Real-time simulation is a valid help to test electrical systems when a physical device is not available. This is significantly evident when used in Hardware and Software co-simulation environment, where it is possible to connect the emulator to a real subsystem to test or validate it. In this paper, a model of the photovoltaic system is presented, that can be implemented within a hardware simulator to be able to interface it with a real circuit, the hardware simulator used is the National Instruments RIO system.

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Section: The Memory Of the Real-time Digital Simulator (Rtds)mentioning

confidence: 99%

Section: Real-time Simulation Architecturementioning

confidence: 99%

Modelling of Photovoltaic Systems for Real-Time Hardware Simulation

Palahalli

Huo

Gruosso

2020

Lecture Notes in Electrical Engineering

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“…Photovoltaic generator during its functioning submits to a set of defects, which they decrease its productivity, such as the cells heating, cells crack, degradation and corrosion of the interconnections [3][4][5]. These defects participate in the appearance of the impedance and the reversed polarity faults, which reduce the power supplies by the faulty generator [6][7].…”

Section: Introductionmentioning

confidence: 99%

Faults modeling of the impedance and reversed polarity types within the PV generator operation

Rezgui

Mouss

et al. 2014

3rd International Symposium on Environmental Friendly Energies and Applications (EFEA)

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International audience— In this paper, we proposed a new mathematical model of the I-V characteristic of a faulty photovoltaic generator. It presents its behavior in normal and faulty operations. In particular, when its basic components such as cells, bypass and blocking diodes are subjected to the impedance or reversed polarity faults. The developed model of the faulty PV generator will allow studying of the I-V characteristic, measures the tolerances of the technical functions, avoids numerous experiments, and ensure better assessment of fault consequences. NOMENCLATURE I ph = Photocurrent standard condition. I 0 = Reverse saturation current of the diode. Z = Electrical impedance R S = Cell series resistance. nc: ncg / ncp = Cell number: good / defective. ng: ngg / ngp = Group number: good / defective. nm: nmg / nmp = Module number: good / defective. ns: nsg / nsp = String number: good / defective. nfg / nfp = Good / defective generator. N Cells = Number of cells in each group. N Groups = Number of groups in each module. N Modules = Number of modules in each string. N Strings = Number of strings in each generator. V / I = Voltage / current. P = Power. I Bypass_Diode = Bypass diode current. V Cell_Imposed = Voltage imposed. a = Diode ideality factor. V t = Diode Thermal voltage

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“…In this paper we present a completely different approach to implement a large, industrial-strength PV parks monitoring system leveraging on the simulation model of PV parks described in Refs. [13,14]. The electrical and thermal equations governing the behaviour of panels and the resistance of interconnecting cables derived from the layout of the actual PV park are considered, thus leading to a compact and numerically efficient model that is capable to account for the interdependency of the thermal and electrical equations.…”

Section: Introductionmentioning

confidence: 99%