Figure 1: PV system installed at Rivière-au-Renard (Canada)
LET MERSEN EXPERTISE PROTECT YOUR SOLAR INSTALLATIONS
ULTRASAFETM US15M FUSE HOLDER
AND HP15M 10X85 AND HP15G 10X58 STRING FUSES
SURGE-TRAP® 1500VDC SURGE PROTECTIVE DEVICES
1500VDC DISCONNECT SWITCHES
HP15NH 1500VDC NH FUSES
1500VDC POWER DISTRIBUTION BLOCKS
EP.MERSEN.COM
solar power
Solar PV Challenges
SOLAR PV SYSTEMS SUBJECT TO EXTREME COLD-WEATHER CONDITIONS
face particular challenges, from the planning stage, to operation and maintenance. Low temperatures, heavy snowfall, freezing rain, and short periods of sunlight are some of the phenomena that may a ect solar PV performance. Due to an ongoing misconception that solar PV systems are not suitable for such conditions, its deployment in colder North American regions remains considerably low.
However, solar PV is the fastest growing renewable energy source worldwide, with an extraordinary 50 percent growth rate in 2016.  is unprecedented growth has also facilitated the development of measures to adapt PV systems to harsh environments. Regarding PV systems in cold climates, such measures can be separated into two main groups: (i) design and technologies and (ii) O&M strategies.
Design and Technologies
During planning and design stages, on-site extreme weather conditions must be considered. Snow accumulations on the PV modules can be minimized by using higher tilt angles, and frameless modules, which helps snow to slide o  easily. Along with the aforementioned con guration, portrait-oriented PV module installation is an advantage; a longer sliding surface will facilitate snow shedding. If high tilt angles and frameless PV modules cannot be used, landscape orientation is preferred, as snow accumulation at the bottom of the covered modules will tend to cover a single PV cell string, minimizing energy losses. For ground-mounted arrays, if high snow accumulations are expected on site, elevated frames are needed.
Even a light coverage of snow on the module surface can have a large impact on energy yield. Bypass diodes are used to bypass covered PV modules, thus minimizing related losses.  anks to recent engineering development, bypass diodes are also included inside the PV modules so that covered PV cell strings can be also bypassed. Proper string/row design can also help reduce coverage losses; the electric connection of a string over two physical rows will produce an undesired combination of covered and uncovered modules, and should be avoided.
in Cold-Climate
Regions
by Sergio Gualteros, Pierre Beaudoin, and Matthew Wadham-Gagnon
26
MAY•JUNE2018 /// www.nacleanenergy.com
Figure 2: Bypass diodes can reduce energy losses caused by partially-covered PV modules
Microinverter-based architectures are superior to string inverters in cold climates.  e increased granularity of this architecture leads to better performance monitoring, which reduces the single-point-of-failure challenge, and minimizes the impact of partially snow-covered PV modules.
O&M Strategies
PV systems installed in cold and isolated regions are subject to logistical constraints for O&M, which considerably increases operational expenditures. Reducing system complexity helps minimize required O&M interventions. For example, sun tracking systems, which comprise sensitive equipment and moving parts, are likely to fail due to extreme low temperatures or high wind speeds.
In order to avoid false-alarm situations, the adverse e ect of freezing temperatures on electronic equipment must also be considered. In fact, electronics are highly impacted
by ambient temperature; voltage, current, and temperature readings can drift when sensitive equipment functions outside its operating temperature range. Utilizing hermetic, temperature-controlled enclosures for electronics, or using military-grade electronics, can help reduce this drift in systems with high precision requirements. To avoid false-alarm conditions in small-scale systems, an overall uncertainty estimation is recommended.
One of the most common concerns in cold weather is removing snow accumulations from PV modules. In an e ort to reduce O&M interventions, self snow-shedding and de-icing must be evaluated at each particular site. Snow cover on a PV module can eventually allow some solar radiation to pass through; even partially covered modules can produce electricity and heat, and promote self snow-shedding. Experience and observations gleaned from the  rst winter of PV operations should provide su cient information to operators. Cleaning tools for de-icing and snow removal must be carefully chosen in order to avoid damaging PV modules.