If you're considering beginning your off-grid journey, you might need to know how much solar power do your house need before buying solar panels to build a independent solar power system. The exact number you need will depend on the size of your home, your electricity usage and the angle shadding and orientation of your roof. On average, you might need between 15 and 20 solar panels to fully power a typical home in US. and the angle, shading and orientation of your roof are key factors in determining how many solar panels you need.
Click here to get more.
Tiny homes are all about maximizing efficiency in a minimal space, and what better way to extend that philosophy than by embracing solar energy?
With the tiny home market poised to reach an impressive $6.9 billion by , more and more people are seeking out sustainable, flexible, and cost-effective living solutions. Let's delve into some key benefits that make solar power a compelling choice for tiny homeowners.
One of the main pain points for any homeowner is utility costs. For tiny homeowners, the motivation is even stronger; 80% cite financial savings as a key factor in their decision to go solar.
By generating your own electricity, you can dramatically cut down your energy bill. Given that the system's weight and dimensions are tailored for tiny homes, you can maximize efficiency without cluttering your limited space.
As we collectively move toward a greener future, solar energy stands out as a sustainable choice. This is particularly true for tiny homeowners, as 35-40% of them already live completely off-grid. Solar power reduces your carbon footprint and aligns perfectly with the ethos of tiny home living, which often embraces a more sustainable, back-to-basics approach to life.
One unique aspect of tiny homes is their mobility; 75% are on wheels and move at least once a year. Solar power systems can be just as mobile. With clever roof-mounted or ground-mounted installations, you can easily set up and dismantle your solar panels whenever you decide to change your scenery, making it a seamless part of your nomadic lifestyle.
Beyond the immediate benefits, installing a solar power system can significantly increase the value of your tiny home. A solar setup can be a powerful selling point, emphasizing savings and eco-friendliness while future-proofing the home. As more people become environmentally conscious, a tiny home equipped with a solar power system becomes an increasingly attractive option in the market.
Before you can set up a solar energy system that meets your needs, you need to understand just how much energy those needs require. Thankfully, calculating your tiny home's energy consumption isn't as complicated as it sounds.
There are generally two ways to approach this: you can either review your existing utility bills for a ballpark figure or create a list of all the appliances and devices you'll use in your tiny home and calculate their daily energy consumption.
To make it easier, we've prepared an example you can use to map out your energy needs:
To find the daily energy consumption, multiply the power rating by the daily usage. For example, an LED light bulb rated at 10 Watts used for 5 hours daily would consume 50 Watt-hours daily.
By mapping out your appliances and their energy needs, you can determine the size of the solar energy system you'll need. This step is crucial in avoiding the disappointment of an under- or over-built system.
And don't forget, tools like the Renogy solar panel calculator are there to guide you through this process, making it even more straightforward.
After figuring out how much energy your tiny home needs. The next logical question is: how many solar panels will it take to generate that energy? There is no one-size-fits-all answer; it varies based on several factors unique to you and your home, including:
That handy table you made to calculate your daily energy needs can be a good starting point here. The more devices and appliances you power, the more solar panels you need.Also, you can look at your electricity bill to find out how much energy your household consumes in a month. This is typically measured in kilowatt-hours (kWh). If your monthly energy consumption is 900 kWh, your daily usage is approximately 30 kWh (900 kWh / 30 days).
Research the average peak sunlight hours for your location. This is the number of hours per day when sunlight is strong enough to generate significant power.
Solar panels need room to soak up the sun, and tiny homes aren't exactly known for their expansive roof space. However, if the roof can't accommodate your solar dreams, consider using ground and pole mounting options. Additionally, high-efficiency panels may cost more upfront but generate more power in less space. This is a boon for tiny homes where space is at a premium.
Your geographical location affects how much sunlight your panels will receive. The angle of your panels can be adjusted to maximize sun exposure, optimizing the energy you can produce each day.
For context, imagine your tiny home needs 24,000 watt-hours per day. A single 250-watt panel soaking up sunlight for 8 hours can generate 2,000 watts a day. Doing some quick math, you'd need about 12 panels to meet your daily energy consumption.
Also referred to as a solar panel's power rating, panel wattage indicates the electrical output of a particular solar panel under good conditions. Wattage is measured in watts (W), check the wattage rating of the solar panels you intend to install. Solar panels typically range from 250 watts to 400 watts each.
Say you decide that solar energy is the way to go for your tiny home&#;fantastic choice! The question is: how do you go from idea to implementation? No need to worry; we have you covered.
Here&#;s a step-by-step guide to illuminate your solar journey:
Like any major project, setting a realistic budget is essential. Solar panels, charge controllers, inverters, batteries, and installation all come with costs. Knowing your budget will help you decide which components to splurge on and where you can save.
Since space is often a premium in tiny homes, you need to decide whether your solar array will go on the rooftop or require a ground-based system. Ground systems are easier to clean and maintain but may take up valuable land space. Rooftop systems are space-efficient, but consider the weight and whether your structure can handle it.
With your budget and placement decided, it's time to pick your panels. Remember, efficiency is a priority, especially when working with limited space. Look for high-quality panels that provide the most power for their size.
The racking system holds your panels in place, either on the ground or on your roof. Choose one that is durable and suited to your specific setup. Ground systems often require a more robust frame, while rooftop systems need to be lightweight yet secure.
Now that you have all the pieces to your solar puzzle, it's time to put it all together. Wiring your system is a crucial step for optimal performance, and doing so correctly will help you get the most out of your solar panel system.
Unless you have experience working with electrical systems, we recommend seeking professional help. Our experts at Renogy can guide you through the process to ensure everything runs smoothly and safely.
In conclusion, determining the right amount of solar power for your tiny house involves a few essential calculations and considerations. By assessing your daily energy consumption, factoring in your location's peak sunlight hours, and selecting the appropriate solar panel system, you can efficiently power your tiny home with renewable energy.
Yes, you can run your entire home on solar power as long as your electrical system is 100% compatible with enough solar panels for your annual electricity usage.
You&#;ll likely only need about 10 to 17 solar panels to power your square feet home each month.
It&#;s hard to imagine that I&#;ve been powering my tiny house off solar panels for my tiny house for over 7 years now! Not having a power bill for almost a decade has been incredible. With that in mind, I wanted to get some real-world experience with my system to give you all the full picture of what it&#;s really like to power your tiny house with solar: how many panels, how much does it cost, and more.
Many people have asked me about putting solar panels on a tiny house because I&#;m one of the few out there that is totally off the grid in my tiny house. I&#;ve had to figure things out like how to run my air conditioning off solar, how to cook with solar in a solar oven, and how I use solar generators as backup power in a pinch.
Tiny houses are a great candidate for solar power because the smaller space makes for low power needs. While the traditional home in America uses around 30 KWs per day, my tiny house uses around 3 KWs per day.
Every decision I made during my tiny house build, from choosing LEDs lights, to a super-efficient minisplit system, and an on demand hot water heater all were chosen to reduce my power consumption. Since I built my own house, these decisions were pretty simple and, in the end, didn&#;t cost me much more. Any additional costs for things like a high SEER rating HVAC system quickly paid for themselves by letting me have a smaller solar panel array and batteries.
A tiny house will use around 4 KWs per day. Typically, around 80% of that power will be used for heating and cooling, assuming you cook and heat water with propane or natural gas.
Here is an example of my power usage breakdown:
Total: 4,150 watts per day
15 solar panels will power a typical tiny house. This assumes an average sized solar panel of around 300 watts, which would generate around 4,500 watts of power from the sun. This would cover all your power needs including some heating and cooling, but require you to have a gas cook range and a propane heated hot water heater. If you live in a particularly cold climate, you&#;ll most likely need to supplement your heating with a propane heater too.
Generally speaking, you can only fit around 2 solar panels on a tiny house roof. This presents a real challenge because today you can really only expect to make around 20 watts per square foot of solar panel in ideal circumstances. That means you&#;re only going to be able to fit around 600 watts of solar production on a tiny house roof, which isn&#;t a whole lot.
Many people want solar panels on the roof of their tiny house, but I opted for a ground mounted solar array, which I highly recommend. Tiny house roofs only have around 200 square feet of space and since most roofs are pitched, you can really only mount panels on one side. This means you only have around 100 square feet of space for panels.
What I did was mount my solar panels on stands on the ground. After considering all the options: roof mounted, pole mounted, solar trackers, and fixed ground mount, I&#;m really happy with my decision.
The benefits of a ground mounted array are huge: being able to easily clean my panels, clear off snow that covers my panels after a snow fall, keeping the panels cooler (increases their efficiency) and being able to shade my house while placing the panels in an open field.
The biggest benefit of ground mounting my panels is that I could have a way bigger solar panel array. This meant instead of 600 watts on the roof of my tiny house, I could put 4,000 watts on the ground in the field right next to my tiny house.
To get your tiny house setup on solar you&#;ll need the following parts: your panels, batteries, a charge controller and an inverter. Simply put, your solar panels take the energy from the sun an converts it to DC power, that then flows to the charge controller which regulates the flow of power to the batteries or the inverter, the batteries stores power for later and the inverter converts the DC power to AC power, which your house uses.
Here&#;s the key details of my solar power system:
My Tiny House Solar Setup:
Before anything I needed to determine the best placement for the solar panels to make sure it had good solar exposure and didn&#;t fall into shadows too much. To do this I used a tool called a &#;solar path finder&#; which is a semi reflective dome that you position at the location, then snap a photo.
The photo is then loaded into a program and spits out a whole bunch of calculations.
If you are looking for more details, kindly visit JM.
Once you upload the image into the software and then trace the tree line outline, you enter in your location, date and time. It then can calculate how much power you&#;ll produce based on 30 years of weather patterns for your exact location and tree coverage. Then it spits out all the calculations:
With that in mind, I knew what I could expect out of the system I had designed. It also was a way to verify my assumptions.
Once I verified that the system was going to be well suited to my needs, I had to build my panel support racking. I did this out of pressure treated 4×4&#;s that were each 10&#; long. These things about 300 lbs each so I don&#;t have to worry about the wind picking up the panels.
I opted to build them because it was cheaper than some of the turn-key option out there and most of the for purchase ones required me to cement in the ground; I rent my land, so I wanted a mobile solution. If I remember correctly it was about $500 in materials to build this part.
Many people have asked why I didn&#;t mount these on my tiny house roof. You technically can mount on your roof, but honestly, the number of panels that you need to practically power your house is too many for the roof.
There are some other major bonuses of being on the ground:
Cleaning your panels is pretty important because you loose efficiency as residue (bird poop) builds up. Also, as I learned just a few days ago, when it snows, you need to clear your panels. Cleaning becomes super simple and a lot safer when you don&#;t have to climb onto a roof via a ladder.
Just this week we got a decent snow, 3 inches, which is quite a lot for Charlotte. The first thing I had to do when I woke up was clear off the panels because, with the snow, they made no power. This was compounded because since it was cold, I needed more heat. I can&#;t imagine having to drag the ladder out and try climbing on an icy roof&#; No Thanks.
Many people have read around the internet that DC (direct current) is a more efficient power way to power things. Generally speaking, everything in a traditional house is wired for AC (alternating current), but if you&#;re putting solar in a tiny house and building your own house, the question becomes relevant when you&#;re starting from scratch. Solar panels produce DC power, so you have to decide how you&#;re going to handle it.
Most of the advice to wire a house for DC power comes from older sources who haven&#;t updated; these could be old articles written on the topic (consider anything more than a year out of date with how fast solar is improving) or from someone who hasn&#;t caught up with the latest equipment.
Back in the days, the drive to wire a house in DC power comes from two main things: there was power loss through inefficient inverters (converts from DC to AC) and from the fact that on paper DC is, in fact, more efficient.
Where this falls down in modern times is that inverters have come a long way and while there is some loss in power through the converting of AC to DC, it&#;s quite minimal. The other factor here is that any inefficiencies (of both the conversion to AC and the less efficient nature of AC) can be easily offset by the addition of 1-2 panels to your array.
This begins to make even more practical sense today because if you wire for DC, you&#;ll be limited to DC powered appliances, which typically cost two to three times the cost of their AC equivalents. That all means that you can actually have more power with AC, even after the losses through inefficiency, for less money. This is because the savings from going to AC appliances over DC will leave you with more cash, even after you buy 1-2 more panels.
To put it simply, convert to AC, add a few more panels to your array and stop worrying about AC vs DC.
After calculating the ideal location and building my stands, I installed the solar panels. This part was pretty quick and the stands worked out perfectly. The panels are 250 watt Canadian solar panels. They are wired in groups of three, then paralleled into the system. To give you a sense of scale, these panels are 3.3 wide and about 4 feet tall.
Next, I built a cabinet to house all the gear. I wanted a stand alone space because the batteries are so heavy. At 118 pounds each, plus cabling and other equipment, the whole unit is over 1,100 lbs. The top and bottom sections are divided so that the gasses from the batteries don&#;t go up into the electrical section for a very important reason.
Looking at the cabinet, on the sides of it, you can see the vents. When you use lead acid (LA) batteries you have some off gassing as the batteries discharge and recharge. These gasses are volatile and can ignite, possibly leading to an explosion. To take care of this I installed two vents like this which provide adequate venting.
I choose lead acid batteries over AGM (absorbent glass mat) because LA&#;s have more cycles and cost a bit less. Lithium Ion at this point is cost prohibitive, around $10,000 for the equivalent capacity. I choose these 6 volt batteries because it was more economical over other options and trojan is a pretty reputable name in the industry.
My batteries should get about - cycles (11-14 years) before I need to replace them. I figure in about 5 years battery technology will have progressed so much I&#;ll change early. New batteries will cost me about $5,000 of the lead acid variety.
The batteries are wired in series parallel. The batteries are 6 volt each, in series of 4 the create a 24 volt unit. Then I have two of these 24-volt units in parallel. The reason I choose to go 24 volts over a 48 volt (which is more efficient) was that the equipment was a little cheaper and it allowed me to future proof my setup.
Going with a 24 volt system also allowed me to select components that I could add more panels and batteries very easily without doing equipment upgrades (just a factor of the abilities of the units I choose). This way I can add up to 15 panels and a lot more batteries without upgrading the electronics. A big draw for me to the system I choose was that I can also stack these inverters, so if I ever go to a normal sized house, I just add another unit and it just plugs into my current one.
In this photo going left to right: Din Breaker Panel, Charge Controller, Interconnect w/ control panel, inverter.
In general, the power flows in the same manner (but not exactly).
Once the power goes through the system it outputs from the inverter as AC power. This AC Power flows out through a huge cable that you can see sticking out of the bottom of the inverter then goes right. From there it runs to this:
This is a 50 amp RV style plug. The reason I did this was twofold. City inspectors are less picky when it comes to non-hard-wired things. This setup also lets me roll into any RV campground and hook up seamlessly.
The plug goes into a 50 amp RV female receptacle. This is important that you don&#;t have two male ends to your cord. This is dubbed by electricians as a &#;suicide cord&#; because if you plug into a power source, you have exposed conductors that are live; accidentally touch them, you complete the circuit and zap!
You want a female end to your cord so that you reduce the chance of being shocked. I also turn off my main breaker at the power source when I make this connection, then turn it back on.
If all these mentions of watts, volts, amps, amp hours etc are making your head spin a little, you may need to go back to the basics. I have an ebook called Shockingly Simple Electrical For Tiny Houses which guides you through all the basics. As of now, it doesn&#;t go too deep into the solar aspects, but the basics of electrical, wiring, power systems and determining your power needs are covered in depth and designed for those who are totally new to the topic.
So once the power passes through the power inlet it goes to the panel. Near the bottom you can see the backside of the power inlet, it has a large black cord coming out of it, into the box and ties to the lugs. From there it goes out to the house.
Here is my grounding wire for my system. This is actually one of two, another is located at the panels themselves. My house is also grounded to this through the cable hook up and to the trailer itself.
A really important note: ground depends on a lot of things, one of which is if you house electrical panels is bonded or not, if you don&#;t know what that means, read up on it, it&#;s very important.
The other component of this system is the generator which I used for the first two years and then opted to upgrade my system because they were such a pain to use. In the winter months, I sometimes needed to top off my batteries every now and then, basically when it&#;s been really cold and very cloudy for a week or more.
I had a Honda EBi already which I really like. It&#;s very quiet and small. The one downside to the Honda is that it only does watts and only 120V and I needed more power and 240V. To charge my batteries, I had to have 240 Volts, which lead me to get another generator, a watt 240 volt Generac for $650. This generator proved to be a major headache and lead me to upgrade my system just to not have to use it anymore.
Here is a video that compares the two generators in terms of size, noise, output, and price.
&#;
The big question when it comes to doing solar or not is of course cost. Everyone would like to have solar, but costs are a real barrier. My decision was made pretty easily when the power company informed me that I would have to pay $15,000 just to run their power line to my house, only to have a power bill each month.
My initial version of my solar panel array and batteries cost me around $14,000 with the added benefit of no power bills ever again and a $7,500 tax credit back, the decisions was a simple one. I later upgraded to a larger system for another $5,000, of which I got another $2,500 tax credit.
So, for me, I was able to actually save money from day one. That said, I had to bank roll that huge cash payment which most people cannot do.
Here is a rough break down of costs for my upgraded solar panel system:
In general, I think for tiny houses in one spot, solar is very realistic. Even if you don&#;t start out on solar, the cost savings of living in a tiny house can let you save up for the install pretty quickly. When I rented an apartment, I was paying $ a month, compared to my tiny house that costs me about $15 a month (not a typo). Living in a tiny house allowed me to save a ton of money while having a comfortable home.
So that&#;s the surface level details of the system, I&#;m going to be doing something in the future which will be a how to size, choose parts, hook up and all the other details of doing solar for your tiny house.
Your Turn!
By
Ryan Mitchellon April 10,
/