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The problem An additional speed bump is the complexity of installing solar: regulation around net-metering. Grid-tied systems. Installation permits (even if you do own your property). Getting quotes from different installers. Solar financing. All complex processes inherited from the construction industry which slow down mass private adoption of renewables. In the following I attempt to bypass both these problems by building a standalone solar power plant on my windowsill with off-the-shelf Amazon parts, and discuss the pros and cons of this approach to solar.
A possible solution? :) Questions remain. Can this system make any meaningful energy? Does it make financial sense?
$211 of components on Amazon is all I need My goal is to take care of the energy needs for just my bedroom. 4 main components are all we need to achieve this: A solar panel to collect, a battery to store, an inverter to convert the direct current to alternating current, and a “charge controller” to balance the three other components. I’m using bargain-basement parts intended for RV, marine & car usage which keeps my system cheap and mobile. Total component cost is $211 ($230 after shipping & taxes). The main components as found on Amazon are above. Anyone looking to build a similar system themselves can view the full component list (shoot me an how it went!).
I ordered the system on July 2nd, and with ground shipping the PV panel ($95) arrived July 11th from Canada, and the battery ($66), wiring ($18), controller ($17) and inverter ($15) arrived July 15th from Amazon USA.
Step 1 Cut and lay bare the end of the battery & inverter wires (battery disconnected, please). The panel’s wires are already bare on one end. Do a dry run connecting battery, inverter and panel to the controller — it should look like above.
Step 2 Detach the panel wires again and place the panel on the rooftop or wherever you get the most sunlight (…garden …balcony …). Attach the panel to something: I zip-tied the back of the panel to a cable which I fastened on both ends around sturdy roof pipes (more photos see ) and run the power lines back to your apartment (drop down the facade and into the window in my case).
Step 3 Assemble the solar controller, inverter and battery into a tighter package. Re-clamp the wire from the panel to the solar controller and close the window. It should look as above. The charge begins!
In the evening, turn on the inverter. My lamp, computer, tablet & phone are all being powered simultaneously here on the day’s solar charge! Self sufficiency achieved?
Daily Power Production:Theoretical: 4.26 sun hours/d * 100W solar = 426Wh/dayActual Production: 350Wh/day
Morning before charge. Evening after charge. My traditional AC lamp is a non-optimized part of the system— I could get DC lights that run off USB to avoid inverting that energy, but have not done so thus far and prefer to just use the cute little thing. When I go to bed I’ve usually used around 30% of the energy anyway— I wish I could run a water heater, heating or fridge off this system to use the excess 270Wh of the daily energy production.
Unless you live on an RV or a boat it doesn’t make financial sense yet (see epilogue #1). But if prices come down a little more (what a difference the last year made!) or manufacturing gets a bit more resource-efficient the scales could tip and this could be a green and fiscally sensible solution (see epilogue #2). And some time in the next decade this great little DIY system that can function as a back-up system today (see epilogue #3) could become a viable consumer electronic: a cheap personal power plant for urban renters.
Solar as a modular consumer electronic — like air conditioning and satellite dishes? If we look to the car, the smartphone, the window A/C unit — these devices spread like wildfire across the globe because they were off-the-shelf products that required no configuration but great benefits. Identical appliances were churned out at an industrial scale for a global audience. They were “plug n play”. Plug n play solar has been around for a while, but has never taken off (probably because behind-the-meter power is still sketchy and poorly understood). The potential for plug n play solar is huge — it could mean cheap, zero-configuration solar energy spreading to consumers at the pace of the smartphone, the car or air-conditioning. This could be a cool Kickstarter project in the future… or a just fun DIY project today.
Financial payback period for 100W system
System cost : $211 on Amazon Yearly energy creation: 365d * 4.26hsun/d * 100W = 155’490Wh/y Yearly value creation: 155kWh/y * 15.34c/kWh = $24/y energy created100W system payback period: $211 / $24 = 8.5 years until payback
The financial payback of the system is 9 years including battery, which is in line with many rooftop systems but doesn’t include servicing. This could be reduced to 6.5 years by adding a second 100W solar panel:Payback period for 200W system
200W System cost: $300 on Amazon Yearly energy creation: 365d * 4.26hsun/d * 100W = 310’980Wh/y Yearly value creation: 311kWh/y * 15c/kWh = $48/y energy created200W system payback period: $300 / $48 = 6.5 years until payback
Note however that after 8 years of daily use the lead-acid deep discharge battery will be spent, which I’m not taking into account here. Either way you cut it, this is not a money saving machine. Energy prices are just too low.Payback period: 581kWh / 155kWh/y = 4+ year footprint payback
An eventual product would use Lithium-Ion batteries once they come down in price, which have a way better energy footprint. Lead-acid batteries are used for now because they’re cheap. So no, we’re not saving any CO2 emissions here until after 4 years — not a green machine. [1]Get updates at