How to go solar?

Five years ago, St. Albert’s Ron Kube was concerned about carbon. He knew that heat and electricity was one of the top sources of heat-trapping pollution in Alberta (coming in second behind oil and gas extraction), and thought going solar might be the best way to do his part for the planet.

That’s when he read in the Gazette about how fellow resident Craig Dickey had one of the most productive rooftop arrays in Alberta.

“He used to live across the street from me,” Kube said, so he called him up and checked the system out.

Two years later, Kube built a $22,000 solar array on his roof to energize his home and an electric car. It now saves him about $3,600 a year on gasoline alone, and he guesses it will pay for itself in about five years.

“It’s kind of the way of the future if you’re concerned about the environment and want to do something,” he said of solar.

“It’s pretty easy to do.”

The rising sun
Solar power is on the rise in Alberta, with some 3,410 grid-tied systems now active in the province, according to the Solar Energy Society of Alberta’s solar generation odometer.

Most of Alberta’s electricity comes from carbon-heavy coal, said Dave Kelly, CEO of SkyFire Energy and an 18-year veteran of the solar industry. Put up solar panels, and you can tap the sun for power for a fraction of the cost and pollution of regular electricity.

Kelly said solar costs have plummeted in recent years to about $3 per watt installed, or about a tenth of what they were when he put an array up on his roof 18 years ago. Most homes can get by with a 2 to 10 kW system, which would cost $6,000 to $30,000 and pay for itself in less than 15 years.

“It’s better than money in a bank account,” he said.

While retrofits are common, Kelly noted that Jayman BUILT now includes solar by default in its new homes with his company's help, and that California requires solar on all new homes.

Dave Pearson went solar in 2015 by putting what is one of the biggest household arrays in St. Albert on his roof. To him, going solar was a way to be environmentally responsible and save money.

“I don’t pay electricity bills,” he said, and he’ll likely have earned back the cost of his system by next year.

Today’s prices make going solar a no-brainer, said Pearson, who works for CDN Power Pac (a company that specializes in renewable energy), especially since many installers let you cover your loan payments with the money you save from solar energy.

“You have to have the ability to pay your utility bill in order to afford solar.”

Do your homework
The first thing to do before you go solar is to rein in your energy use, said Kube. The less you use up front, the less you have to spend on solar panels.

“It doesn’t really cost you anything to unplug the old beer fridge in the basement,” Kube said, and in his case said fridge accounted for about 10 per cent of his power bill.

By switching to LED lights, using power bars and efficient appliances, and shutting off stuff when it wasn’t needed, Kube said he and his family slashed their annual power use to about 5,200 kWh from 12,000 kWh. He suggests using a watt meter (such as the ones included in the St. Albert Public Library’s HEAT Kits) to find the big energy hogs in your home.

Kube and Kelly said to hire a licenced electrician to design and install your system, as there's a lot of permits and engineering involved. The Solar Energy Society has a list of qualified installers.

Data from the NAIT Reference Array in Edmonton suggests that Edmonton-area solar panels should be set at 53 degrees for optimum production. Kelly said a south-facing roof is best for this hemisphere, but anything but north works. If you’ve got 20-year-old shingles, you should replace those before you put panels on top of them, as it’s expensive to take them off to re-shingle.

Most solar systems feed power into the grid and don’t have batteries, Kelly said. If you want batteries (e.g. to live off-grid or have power in a blackout), expect to pay a lot of money.

Pearson and Kelly said most solar systems come with 12- to-25-year warranties and last 30 to 40 years. They require very little maintenance apart from checking the inverters every so often – you don’t have to wash them, and it’s not worth clearing snow off them (the panels don’t produce much in the winter anyway).

Is This The Next Big Thing In Solar?

Solar power installations out in the open are a common sight in many parts of the world, but how about household solar generators? A team of Swedish and Chinese scientists recently reported this might become part of our future after they successfully converted indoor light to electricity using organic photovoltaic cells.

Organic photovoltaic cells, or OPV cells, are a third-generation solar technology that holds a lot of promise as a cheaper alternative to previous generations of solar cells. They are flexible because they are made of two layers of semiconductors, which are made of plastic polymers. This flexibility makes OPV cells attractive for various applications, but they are particularly attractive for the building-integrated segment of the solar industry.

Interestingly enough, scientists studying these cells are not unanimous in how exactly they work. They know that when the cell absorbs a photon, it displaces an electron in the polymer atom, and this displacement leaves a hole. The hole bonds with the displaced electron creating what scientists call an exiton. This exiton then splits and the electron it releases goes on to bind to another hole, created by another photon. As the electrons move from hole to hole, they create an electric current. What makes the exiton split, however, is still open to debate.

This may be curious, and it might have implications for making OPV cells more efficient, as their average efficiency rate right now is just 11 percent. But until scientists discover what makes the exiton split, they are making advances elsewhere.

Researchers from the Linkoping University in Sweden, the Chinese Academy of Sciences and the University of Science and Technology in Beijing developed new polymers for the active layer—the one that absorbs the photons—of an OPV cell. This made it possible for the cell to generate power from ambient indoor light. The power, for now, is not very great but, according to the scientists, with further work, it could increase enough to power various devices that will be part of future households in the era of the Internet of Things.
Related: This “Anti-Solar Panel” Could Generate Power From Darkness

“We are confident that the efficiency of organic solar cells will be further improved for ambient light applications in coming years, because there is still a large room for optimization of the materials used in this work,” one of the researchers, professor Jianhui Hou from the Chinese Academy of Sciences, said, as quoted by Photonics Media.

"The digitalization of our society is ramping and Internet of Things and smart devices are a strongly growing market," another of the authors, Jonas Bergqvist said. "Many of these devices consume low amounts of power and efficient light energy harvesting devices can help powering them. The high performance OPVs combined with printing and coating roll to roll production shows a great potential to power connected smart things."

OPV cells are cheap to make and they can be printed on large surfaces in a printing press. This makes them a valuable addition to the growing industry of solar power technology as long as the challenge of efficiency is solved, along with the other main problem with OPVs: durability.

Solar Technology Will Just Keep Getting Better: Here’s Why

With the federal Investment Tax Credit phasing out, it’s a good time to take stock of the solar industry - both taking a look at where it has come from and where it is headed, especially in terms of innovation and evolving technology. 

There are few individuals more qualified to discuss this topic than Jenya Meydbray, Founder and CEO of PVEL (PV Evolution Labs).   His company – founded in 2010 - performs independent qualification of photovoltaic solar equipment on behalf of large buyers and investors (PVEL tests both thin film and crystal silicon panels, but the vast majority of technology in the market is crystal silicon – which is where investors and developers are seeking the data). 

A solar power plant is a capital-intensive venture, with an expected lifespan of as many as several decades.  Operations and maintenance costs are relatively marginal, and the fuel is free, so the quality of the panels is perhaps the most critical element to consider in the overall equation. 

As Medbray comments, “Manufacturers are selling watts, while customers are making money off kWh and those are two different things.” This dynamic becomes increasingly important with assets that must perform over a large variety of conditions and lengthy timeframe.  He asks rhetorically,

Have you ever seen a plastic kid’s toy left outside for a year? Polymers and plastics degrade in the field and solar panels are no different – they have polymers and plastics. We try and make it as simple as possible to provide comprehensive solutions through our qualification program. 

PVEL evaluates panels by applying sophisticated reliability and performance-testing programs to ensure the panels will perform as promised and investors can feel confident ponying up their cash.  It’s no small challenge, given that the cell and panel technology continues to evolve.  And the industry has already come a long way since Meydbray started.

A look back at the past decade of innovation

Meydbray comments that from an outsider’s perspective, a solar array “looks like a rectangle of crystalline solar cells glued to glass, bolted to a rack that goes through an inverter.”   In that sense, he says, solar panels haven’t changed much in ten years and today they look more or less the same, “They still have 72 crystalline based cells glued to glass, bolted to a frame, and interconnected with an inverter.”  However, he likens the cells to an engine in a car – an engine that has evolved greatly in the past decade, and whose costs have fallen dramatically, to perhaps 20% of what they were ten years ago. 

Meydbray catalogs the items driving that trend in cost reductions, with one of the biggest levers being improved efficiencies in the manufacturing process itself.  Take the utilization of silicon, for example.  Although the price of silicon has plummeted from highs of $400 per kilogram to around $10/kg today, it’s still the most expensive input in a solar panel (for multi-silicon, an estimated 15-17% of total costs of goods sold).  Thus, any ability to reduce the amount of silicon helps slash costs.

He cites the concept of ‘kerf loss,’ a term for the silicon lost in the sawing process during which raw silicon ingots are cut into cells.  If silicon were wood, this would be the equivalent of sawdust that would go to waste.  When a solar wafer – the precursor to the finished polished cell – is made – one essentially slices a giant log or brick of silicon into wafers.  The widespread introduction of ultra thin diamond wire saws several years ago vastly reduces the amount of silicon lost in the process.

Meydbray observes that the cells thicknesses have stayed at about 180 microns for some time. Efforts to produce thinner cells resulted in frequent cracking during the production process, reducing overall yields. However, the widespread introduction of the diamond wire saw has recently allowed for the creation of thinner wafers (and therefore cells), though these haven’t yet moved into commercialization.  He estimates the cost impact to be 1.5 cents/watt for every 10 microns of wafer thickness.

Then there is the conversion efficiency of the cell itself – how effectively it converts photons into a useful stream of electrons.  This is important, since with higher efficiencies you get more watts out of the same rectangle of glass, the same frame, inverter, and labor.  Since 2010, he notes, the absolute efficiency of the crystal silicon solar panel has gone up about .5% per year and “that’s pretty consistent.  That’s huge.  And it’s fundamental to continued cost reduction.” 

One recently applied approach in this area, simply slicing cells in two (a technology referred to as ‘half cut cells’), has helped cut costs by adding five to seven watts of additional power per panel.  That’s because the panel’s electrical current gets cut in half (current being proportional to the size of the cells).  Since the resistive losses are proportional to the square of the current, this approach results in meaningful gains.

In general, efficiency improvements have generally come in waves and largely, but not entirely, out of China.  In 2012, Meydbray comments, the first round of import tariffs was slapped on Chinese panels.  These tariffs were focused on the cell - rather than the panel - level.  As a consequence, Chinese manufacturers started sourcing much of their cell supply from Taiwan while continuing to assemble the panels in China. During this period, innovation slowed down considerably.  PV technology was dominated by the traditional aluminum back surface field (aBSF), with little innovation until 2014, when the tariff loophole was closed and cell manufacture migrated back to China. 

With the aBSF solar cell, Meydrbray comments, one could achieve a 20% practical maximum conversion efficiency.  To advance past that, it was necessary to add an additional layer to the back of the cell.  Cell manufacturers began to innovate and created a new cell technology called ‘Passivated Emitter Rear Cell (PERC).  The PERC technology had the advantage of reflecting previously unabsorbed light back into the cell for a second chance to convert it into electricity. 

The Germany leader in making the cell manufacturing machines – Meyer Burger – figured out how to make the machines to manufacture PERC at scale, adding a “reasonably complex” additional step, he says.   Soon, though, everybody figured it out, to the point that today one can now buy generic Chinese manufacturing equipment for one-third of the Meyer Burger tool and PERC has been widely adopted. 

With PERC, Meydbray says, 23% cell efficiencies have been achieved, with average efficiencies at around 21.5% in the tens gigawatts of cells now being produced annually.  He believes there is some efficiency runway left with PERC, but 23.5 % is probably the maximum that can be squeezed out.  Meydbray also comments that the distinction between mono and polysilicon cells is not as critical as it used to be. “Within these cell technologies, you can use multi or mono cells.” Mono cells used to couple higher efficiencies with higher costs, but “At this point, mono is becoming the same cost as multi, and in some cases is even cheaper,” he says.

Meydbray indicates the solar R&D universe is now working on two technologies: heterojunction – which is a totally new cell technology (Meyer Burger is also working on this – which would necessitate a totally new greenfield solar manufacturing facility) and passivated contact “”which is incremental but difficult.”  The jury is still out on both of these, but he comments “we have a few years before we need to it to go up the efficiency curve.”

And then there’s bifacial

Meydbray indicates that once the PERC cells were created, it opened up an opportunity for bi-facial panels, which are just what they sound like; symmetrical solar panels that can harvest energy from each side.  The original aluminum BSF solar panels were not symmetrical, but PERC is, “so when everybody moved to PERC they were essentially manufacturing bifacial solar cells.  All you had to do was take off the back sheet and you had a bifacial panel.” 

The manufacturing process for the industry giants like Jinko, Longi and others was “borderline trivial” he says, once they began making PERC cells.   Clear back sheets had to be added and junction boxes (the enclosures on the module where all of the PV strings are connected that allows each module to be linked to the next) relocated to avoid blocking sunlight, but those were small obstacles.

As Meydbray explains it, the real challenge with bifacial is not in the manufacturing but in the implementation in the field, because a large number of new variables get added into the equation.  To get best results from bifacial, one must maximize the amount of sunlight reflecting up to the downward facing panels.  The panels must be high enough above the surface to allow maximum reflectivity, but the higher costs of steel racking affect the overall value proposition.  One must also be careful to avoid having the frames block sunlight. 

Placing panels higher off the ground, especially if they are on trackers that tilt the panels to follow the sun, also changes the potential wind loads to which the systems are exposed.  In extreme cases, Meydbray comments, “we have had wind-related failures from trackers.  They can oscillate and blow apart.” More steel can address that, but at an additional cost.

In addition, there is the issue of the mismatch between bifacial modules on edge of the system versus those in the middle that see less light on the backside.  The modules are connected strings in parallel, feeding into a combiner box and inverter.  Since they are in a series, they require the same current. Thus if the modules on the edge see more light than those in the middle, there is greater potential for mismatched losses. 

Despite all of these various factors - and there are over a dozen to consider - Meydbray characterizes the ‘bifacial gain’ (the additional output compared with monfacial modules) as ranging from 5% to 20%,

it’s all about design conditions and cost optimization…bifacial will almost always beat monofacial economics – it’s the largest single step function improvement in levelized costs of electric since the introduction of trackers.

Meanwhile, other improvements are being made across the spectrum

The cells themselves have been increasing in size.  What used to be a standard 156.75 millimeters (mm) cell was initially increased to 158 mm, and Meydbray indicates that cells are now moving to 161 mm.  Longi - The world’s biggest monocrystalline silicon module maker, with plans to produce 30,000 MW of modules by 2021- recently announced a move to 166 mm, with plans to switch its entire production over by 2020. 

The growth is relatively incremental, he says, “moving by one, two, three, or four millimeters…Somebody realized solar cell manufacturing equipment could fit a slightly larger cell” with the result that manufacturing costs fall on a per watt basis.  When you get to 166 mm, though, it’s sufficiently bigger that you need incrementally different designs in the cell manufacturing equipment. 

Meydbray cautions that with every incremental incremental design change “there are implications that are often overlooked until you have failure” or at least significant challenges.  For example, if one makes the cells bigger, without changing the number of cells in the panel, then the panel is no longer backwards-compatible.  This means that a new and slightly larger panel cannot be retrofitted into an existing field if older panels malfunction.  Or in the case of systems with trackers, a slightly higher panel might increase the torque forces from the wind, which are proportional to square of height of the panel.  As a result, one must either risk failures or invest in incrementally more expensive racking structures.  In that sense, everything is an interconnected ecosystem.

 Solar is a game of shaving pennies.  Other incremental improvements are also taking place, further driving down costs or increasing efficiencies.  Take busbars – the thin flat wires that collect the current created by the cells and connect each cell to the next, ultimately delivering power to the inverter, that in turn sends it along to the grid.  These busbars, Meydbray says, are somewhat like the blades in razors.  From an initial starting point of two busbars on a cell, there are now typically five, which increase redundancy in the event of failures.  Meanwhile, the busbar widths have been reduced to minimize overall cell shading losses.  The next step here is changing the interconnection design altogether, “so that we are now up to 12 busbars that are extremely thin.  Meyer Burger is currently making a metal grid with 30, 40, or 50 wires they call smart wire, which will create further optimization in the cell interconnect.” 

Meydbray points to another emerging approach called shingling.  In the panel with its individual cells, there is space between each cell, where light is not hitting active solar material.  With shingling, the cell is cut into five or six strips and overlaid like shingles on rooftop, “so you have complete coverage of the real estate of the solar panel…It’s now on everybody’s technology road map.”  And it can be undertaken with both PERC and aluminum BSF technologies.

There are also other tiny adjustments that add up, such as a tape from 3M that addresses the light that reflects off the busbars.  This thin tape redirects light at an angle so it reflects off the glass and gets reabsorbed by the cell, squeezing more efficiency out of the panel.

And finally, there are anti-soiling coatings being developed to minimize losses that occur when panels are compromised – as much as 30% or more - by layers of particulates from air pollution, or dust from weather or agricultural activities.  Washing panels is expensive, “A crew with hose spraying down panels is on the order of 25 cents per solar panel for a large site,” he notes, so a coating that minimizes the need for cleaning helps further lower costs and improve efficiencies.

The bottom line, Meydbray summarizes, is that “there has been a ton of technological innovation over the last decade and its not slowing down. It’s continuing on the same trajectory.” And as costs continue to fall, he predicts, more markets will continue to open up. 

There is always the next horizon.  Solar was adopted first in places where electricity costs are high and it’s sunny. Then as costs fall, there is always the next market where it’s cheaper than the conventional incumbent.