How Many Solar Panels To Power A Fridge

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Do not forget that once every day or so the modern fridges go into a "Defrost" mode. My GE, runs between 84 and 108 Watts, but at least 1 time a day it goes into a Defrost mode which can last up to 2 hours and stay at 315 Watts for those 2 hours. On my BrulTech Energy Management program it shows a rather large spike for that time frame. Normally the fridge mostly stays in the 80-90 range. On days where we were not home (vacation) the fridge averaged .8kW and on those days where the defrost kicked on it was 1.4kW. I have about 5 years of data by the minute.... lots of data

A couple of lessons learned from keeping the fridge running during and after a hurricane -
1. Room Temperature matters the hotter the room the longer the fridge will have to run to maintain temperature.
2. I found as the days without grid power increased the longer the fridge would run per cycle (longest cycle period was 6hrs)
3. The fridge may have additional features that can add to your power consumption (defrost cycle, heat strip around the freezer door)
4. Fill dead space with water bottles 👍 this is just good advice from an efficiency standpoint but extremely valuable when attempting to power your refrigerator without grid power.
5. Consider limiting wasted power by cycling the system on and off. And use a cooler for items people may grab between cycles - this is where the frozen water bottles really shine 👍🥶👍
Also I had to phone a friend on this one - My fridge was off for 4hrs and I plugged it in and the compressor didn’t start. I Checked the wattage and saw it was drawing over 300w but did not appear to be running. My friend said give it 15min it’s probably in a defrost cycle 🤦🏻‍♂️ I had been dealing with so many other catastrophes that I automatically assumed the worst 😂 15 minutes later the fridge started running just fine. If the cell phones were down I would have emptied my fridge into a cooler and planned on grilling the next day 🍗🍖🥩🍔…😂

For anyone interested you can control the defrost cycle on a fridge. Unfortunately, it is not part of the fridge settings. About 5 years ago a fellow RVer bought a Frigidaire residential fridge for his RV, but noticed that the defrost mode was killing his battery setup when it would kick in. Knowing that I was into electronics he asked for my assistance and I downloaded the fridge's wiring diagram and set him up with a manual switch/relay to deactivate the defroster when on battery power. Still works like a champ. I even sent him a diagram on how to automatically switch the defroster mode off when dry camping.

I live on a solar independent offshore cruising sailboat with 400 watts of solar panels and 460 amphrs of battery storage. I have a refrigerator/ freezer I built out myself. The average retail refrigerator freezer is garbage. Consumers will not put up with 5”-6” of insulation and top loading, but that’s pretty much is what it takes to make an efficient refrigerator/freezer in the tropics. The boat is charged by 10:30am in the morning and can go for a week with no sun. Most of it comes down to proper frig. box construction and covering conductive, radiant, and convective heat flow properly.

For frugal people who need only a tiny amount of fridge space, here is an alternative. We used to go on mid-summer vacations in Greece in our small two-person camping car. We used a tiny 18-litre (5 US gallons) Swiss-made fridge attached to the car battery. It uses the same efficient compression technology as a big fridge and is very well isolated. (The isolation probably takes in more than half of the total volume.) Moreover, it opens at the top, so the cold tends to stay inside even when the lid is open.
We set this fridge to very cold while using the car, even though that meant our (Greek) yogurt might freeze. We rarely stayed longer than 2 days in one location, always lonely locations with no electric power source. We always took the fridge off the car's battery to avoid getting stranded. We did not add new food to the fridge while stationary, and never opened the lid for more than a few seconds.
We obviously parked the car under trees, but even so it got very hot inside. The food in our fridge went from frozen to slightly above regular fridge temperature in these days. Occasionally we stayed up to 4 days in one place. This just required reconnecting the fridge once, on a less extreme setting, and letting it run for an hour off the full battery.
All these measures were perfectly sufficient. We also used common sense in other ways, and so we never had food going off for lack of refrigeration.

Others in the comments have mentioned the thermal mass of the contents.
For both freezers and refrigerators freeze gallon jugs of water and use them to fill up empty spots.
The thermal mass will help regulate the inside temperature and in the event of a true power outage or multiple days without recharging keep the contents cold minimizing the on/off cycles.

Refrigerators are much more efficient when they are fully loaded and have reached the desired temperature. The door of a fully loaded refrigerator can be briefly opened to access the contents without causing a measurable drop in the temperature of the thermal mass. There is less cold air volume in a fully loaded refrigerator (because the contents occupy most of the internal space). On the other hand, when the door is opened on empty refrigerator, the heavy cold air drops to the floor and the ambient warm (or hot) air takes its place and the refrigerator must energize the compressor to restore the desired temperature.

Useful information! We have a 20 cubic feet bottom-freezer refrigerator in our off-grid house. As several people below, I disabled the defrost circuit, and manually defrost the freezer section twice a year. I recently bought an additional freezer from Costco - an 11 cubic feet upright model without a defrost feature. Adjusted to -13°C (8.6°F) it draws an all-day average of 32 Watts continuous power - drawing around 80 Watts, then cycling off. Simple "bang-bang logic".

I had NO idea that the conversion form DC to power standard AC appliance was such an energy hog; the fact the small inverter consumes as much power as the fridge it was feeding into is shocking. Excellent content BTW; thanks!

Fine tunes:
1. Where applicable, (portable, etc) A DC fridge will save you all the inversion loss and make it simple to connect a home brewed cheap battery pack for 1-2 days poor sun run time.
2. A capacitor in a box will solve start up draw on either system, so don't have to design to a power level you only cycle 6 times a day.
Great presentation! If you did the above, I'd love to know how much smaller you could tweak your power supply array for a similar DC fridge!

Scott - thank you for the discussion on consumption, watt hours, & capacity in detail that even a solar novice like myself can understand

My experience has shown after building three systems, it’s best to have at least twice the amount of panels, batteries, and inverter just in case! Especially in the winter.

A chest freezer/cooler is ALWAYS going to be more efficient due to the fact of opening the lid (cold air sinks!) You don't have the outrush of cold air like you would on the upright fridge/freezer, so less airspace turnover on the chest. Additionally, you have to consider "thermal mass" as a buffer. It's NOT efficient to keep a completely empty freezer or fridge. Augment the thermal mass of the chest freezer by adding in 2-liter bottles of frozen water to keep the temperature variance at a minimum...keeps the system from working so hard and can also tide you over for those sunless days!!!

I HAVE 6, 100 WATT PANELS ON MY SYSTEM. 60 AMP CHARGE CONTROLLER, 8, 100 AMP 12 VOLT LITHIUM BATTERIES AND 1500 WATT INVERTER WIRED FOR 26.6 VOLT SYSTEM. IT RUNS MY FULL SIZE REFRIDGERATOR, 40 INCH TV, OVERHEAD LIGHT, INTERNET ROUTER, 2 SECURITY CAMERA'S, COMPUTER, CORDLESS PHONE, LAMP AND ALARM CLOCK IN BEDROOM, AND SEVERAL CORLESS DRILL CHARGERS. HAS BEEN UP AND RUNNING FOR A LITTLE OVER A YEAR NOW AND HAS PERFORMED PERFECTLY SO FAR. AND WILL RUN ALL THAT EVEN AFTER UP TO 5 CLOUDY DAYS. LOVE MY SOLAR SYSTEM.

I performed a test powering my fridge for two hours, four times per 24 hour period.
I also ran a test similar to the ones used here. The differences in results were dramatic.
While the temp inside the fridge did vary two-three degrees more during the first test,
it was well within a safe zone for refrigerated/frozen foods. Moral: You can vastly
extend the time you can power a fridge by eliminating the inverter "idle" time.

I'm an engineer and I find all of this fascinating. I lived in southern California for decades and 40 years ago we even had parabolic solar water heater panels on our roof. Today we live on the Gulf Coast. We get plenty of sunshine, but have hurricanes that require some form of alternative electrical generation. I installed a 24kW Generac natural gas generator and an automatic transfer switch. I choose to leave solar gathering to the utility companies for economies of scale. While it's fascinating, without wasteful government intervention the DIY power generation concept doesn't make economic sense. In my humble opinion of course.

A few small lessons learned while boondocking on solar:
1.) Put an equal amount of thermal mass in both refrigerators. The chest fridge doesn't care but the upright should use less energy recovering from door openings. A couple cases of beer make a good foundation. ;)
2.) Put the Ecoflow in stand-by mode or turn it off altogether and only run it periodically to maintain a "safe" temperature, reducing unnecessary compressor run time. That could save 250-300Wh.
3.) In most refrigerators a power cycle will reset the defrost timer. This will prevent the upright refrigerator from using unnecessary power defrosting the freezer. The chest fridge doesn't have a defrost cycle so it saves energy right off the bat. I'd bet a dollar that you can reduce the total daily consumption of the large/Delta Pro setup by 30-40% with a few small tweaks.

Nice video. I liked the calculation tutorial. One thing to work into another video like this, besides running the test for a week or two, is to make sure the appliances are plugged into the EcoFlow units with 25' to 50' extension cords since most people will not be able to place their fridge right next to their EcoFLow.

I did an energy consumption survey on my house two years ago, my Samsung side by side refrigerator pulled a peek of 460w when in defrost mode, 380w in-rush on compressor motor start and average around 80w running with the door closed and 100w with the door open and lights on. All in all, my 2.5hp grundfos well pump is the largest load in my house after putting a soft starter on my 2ton ac unit.

i have a 54quart 12v dc fridge which i got for 100 bucks. turns out it runs fine on 28v and hooked it up to a high efficiency gan 140w power adapter through a pd 3.1 trigger board at 28v. with some additional modifications like covering it in aluminum foil tape, I got the power usage down to 150wh/day lol. no inverter needed and if your pulling from a power bank you dont even need the gan adapters which loose about 6-7% efficiency.
by your math i only need like a 50w solar panel lol. 100w would probably be more ideal. i think those are like 30-40 bucks now.
i should probably make a video about my setup. aint no body never heard of a usb-c powered fridge.

You did aq great job presneting the information. This video is very relative to our situation. We went through a similar method when we sized our solution. We used a battery monitor system like the Victron BMV-712 to understand the power needs of our system in real world situations prior to upgrading batteries or adding solar.
We have a class A RV with a residential refrigerator. The original lead acid house batteries were challenged by the refrigerator. We replaced the four 6V lead acid batteries (Serial/parallel configuration) that had around 200Ah of usable power or up 2400Wh. Of course we would never get to 2400Wh because of Peukert's law. Our initial upgrade was for four 12V 100Ah LiFePo4 batteries. This reduced the weight from about 240lbs to 120 lbs., improved the usable power to over 5kWh, and reduced charging time. (LiFePo4 has a much better charging profile than lead acid). The additional capacity deduced stress about needing to charge the batteries because of the refrigerator.
The next upgrade was to add solar. We added six 200W solar panels to the RV. We working with a budget and decided to create a design that would allow us to add two additional panels in the future to increase from 1,200W of solar panels to 1,600W. This was in a configuration of four on one solar charging controller and two panels on another solar charging controller. The panels are wired in series to increase the voltage and permit smaller cabling.
The other change is we upgraded the inverter charger to permit the entire RV to be powered. Originally the inverter was used for the refrigerator and a couple of outlets through the RV. Combined with adding soft start devices for our RV AC units, we now can run anything in our RV off the batteries. The goal was to be able to run the AC units overnight when we need a little cooling while dry camping or a couple of hours during the day while we were a way to keep our pets safe. (We also have an auto gen start if the batteries run low as a precaution.)
One additional consideration is the power draw of Starlink. We use Starlink when we cannot get cellular internet service. As it turns out it draws more power a day than our refrigerator. Starlink also has a continuous draw. We reduced the daily use by putting it in sleep mode about 5 hours per night.
To fully realize our system we added an additional four LiFePo4 100Ah batteries to expand our power capacity to over 10kWh of capacity. This is the configuration we used to travel to Alaska this year and spend over four months traveling through Alaska and spending a lot of time try camping. The only time we had to use our generator to charge is when the weather did not permit effective solar charging. On good days we would be fully charged by early afternoon.
We also purchased a Ecoflow Delta 2 as a portable power source so we can have the flexibility to permit me to work if the RV is located in a location with a lot of tree cover. We can take the Ecoflow way from the RV in camp and setup the Starlink and charge my laptop while I work through the day. If required I can pack all of it up in the car and drive to a location to work. It is not uncommon for people to stop and look or ask questions when I have the Ecoflow, Starlink, and my laptop setup on a picnic table working. The 1kWh or battery provides enough power for me to get through a workday with Starlink, laptop, and charging my phone.

Cool. You mentioned maybe wanting to use worst case numbers for solar radiance to be safe. That's smart especially for some places, but one thought I had is; many places with low solar radiance in winter are often cold enough that, if you have a power outage, you can just put the stuff outside in the snowbank or porch. So you might not always have to use the lowest numbers there.

My fridge freezer has been running on my Delta Pro, Powerstream inverter (the AC is never on, the PS inverter uses 16W), an EF smart plug and 1600W of solar for over a year now. For an entire year it used 339.78kWh and that’s using it normally, opening the fridge 10-20 times a day as a family fridge freezer keeping cool what’s in it, cooling what we put in it and regularly freezing pots of ice cream made in our Ninja Creami.
I now have another couple of smart plugs linked to the system providing power to the main bedroom and lounge for an Apple Mac mini, 32” monitor, a 55” TV, a 32” TV, a couple of iPads and iPhones along with the router and other vampire power draw devices. I also have the inverter set to provide 30W of power to my home circuit.
Only in the very depths of winter do I need to top it up at night with half price power from the grid, my power bills are essentially just the standing charge, the cost of top up and whatever we use in the kitchen for cooking.
Well worth the investment imo, especially given the now proven longevity of Lifepo4 batteries.

One comment about the sizing of the panels. Your calculations were great for clarity but you did calculate a 3day battery holding capacity and a 1 day recharge capacity. Frankly, you could cut the panel capacity in half and theoretically keep up. For other reasons, I’d use your numbers, though to rebound as quickly as possible. But the other recommendation I would make is look to the pricing. If your calculations suggest 1200 watt panel capacity but you can buy and size a great 1000 watt system, I’d say do that and pickup a small, portable generator and keep a “weeks worth” of gas on hand. In January or super cloudy times, you may run the generator a couple of hours every 2/3 days to replenish. What I like about that is you can double up and run the generator when you need to use power tools or a water pump or a pressure washer, etc, and you don’t have to run a generator at night. Another factor is that over sizing your system a little is wise. But, as you grow the system for more functions (lights, cameras, entertainment, etc), you can thin out the margin of safety because they should not all need extra at the same time. Plus, the more devices on the system the more options for picking and choosing what to power down for the sake of prioritizing other devices. But, this is a great presentation and the importance of factoring loss is huge. Thank you for mentioning that!

after looking over the hourly electric meter readings (exported from the electric company) of our home for the last 8 months, we've got about ~650W of constant draw at any given hour, I'm still taking kill-a-watt readings of some appliances but 158W from 3 out of the 5 of our food/drink appliances.. minus some other stuff around the house, I'm still short 200~300W being accounted for. I made sure the temps were ~37F or ~0F inside them to cut down any unnecessary draw but the biggest unknowns are the [newish] central air system with an electric filter. I think the biggest surprise was the HEPA filter on fullblast was ~150W (two fridges or three freezers worth), but on minimum it's still as much as our fridge. We buy cows/pigs from a farmer, processed by butcher, stored frozen here (some risk on our end but we count maybe 3 days a year for power outages, fixed within 24h).
I was considering solar+battery to cover this constant draw to potentially minimize the electric bill (rates increased ~30% this year), the pattern of our usage is 'food needs to be cold' so it's not really going to change for the next 10~20yrs, so thank you for mentioning that bit about the inverter needs to cover its own cost of operation and how much it may need.
perhaps I'll have to start flipping breakers overnight to find the last bit unaccounted for, it's harder to do that with so many appliances already deployed on different circuits.

Excellent video! I'm in the "crawl walk run" phase now with solar so this info hit the spot! Thanks!

Thought I would add somewhat related info describing what I have going on at the moment. I have two Ecoflow Delta 2 Max units. Each one has a 2048 Wh capacity with a 2400W continuous output and a surge of 4800W. Following are the specs as measured by my PN2000 watt meter for my fridge and my stand-alone freezer. The meters were on the units for over a week to try to catch all the intermittent cycles.
Café Energy Star 27.8 Cu Ft Smart 4-Door French-Door Refrigerator = Average KwH 0.0664 / Daily KwH = 1.5944.
Frigidaire 13 Cu Ft Upright Freezer = Average KwH = 0.0376 / Average Daily KwH = 0.9014
The Delta 2 Max will run the fridge for approx. 21 hours with no input and the freezer for 38 hours with no input. (I’m guessing the missing 0.4 KwH on the fridge is being used by the inverter.)
I just had two GSD7G72M-550WT panels delivered and hope to get them set up this weekend. These are 550W Bifacial panels with a VOC of 49.92 and a ISC[A] of 14.00. The Delta 2 Max will accept up to 60 volts and 15 amps on each 500W input (1000W total PV input per Delta 2 Max) so I should be able to keep these boxes running even under less-than-ideal conditions. Oh, I’m in the Phoenix, AZ area.

I would like to see a national campaign to advocate for inexpensive soft starts to Blunt the inrush. I know there are some relatively inexpensive ones for things like circular saws but the ones designed for a normal AC circuit are obscenely expensive period just my 2 cents

Great idea, I think I'll try it. A note of caution: If your in a situation of high ambient temperature, and especially, humidity, the evaporator will accumulate ice more quickly, and therefore, require a defrost cycle more often, failure to provide this will cause the refrigerator section to loose cold air flow because of the clogged evaporator. The freezer section will probably still operate sufficiently though.

If you take control of the fridge power youself (more recommended for basic fridges), then instead of the fridge turning off it's compressor, you just shut the invertor off entirely, you will save a lot more power. You will need a bit of "integration code" to link the invertor smarts to your own tempsensor though.

When you talk about fridges, the ambient temperature should be noted. Looks like they are in a garage maybe? What is the low, high, average temperature during your test?

I've been looking for a reference like this. Great job in breaking it down so neophytes like me can understand it.

Not All fridges operate the way you described with short duration peaks followed by longer periods of low/no load. Newer inverter driven compressors will run longer durations at lower power as this is more efficient.

Yeah, like some have mentioned, you need to include the thaw cycle if you have a frost free refrigerator. On mine, it's about 400 watts for about 30 minutes. Not completely sure how often it happens but it's at least once a day. And the start current on my fridge (which runs at about 120 watts) peaks at about 1800 watts for a fraction of a second.

THANK YOU! Other than explaining to me why I don't want my fridge to die you did not veer off into odd territories. So it was very straightforward and easy to understand!
Liked and subbed

Thanks for the video!
I didnt realize those portable power sourses were so inefficient

One comment about solar availability, a heavy overcast winter day results in the solar panel putting out 1/14 of its official power rating. The good news is that keeping food cold in the winter is easy. 😉 the covered porch runs about 20 to 30 F.

Great info, i have worked out my fridge daily power usage but never factored in the inverter loss.

Your videos are always excellent. I am not sure why you have not broken through the algorithm game and have 500K subscribers. Well done. Just a suggestion, no one has really attempted to use a 12/2 UF-B at 250 Ft (at less than 20 amps) as a replacement for PV wires to see the voltage degradation and compared that to PV 8 or 10 gauge. It would be a cool experiment.

The most interesting thing to me is all the refrigerator power consumption numbers from both the video and the comments! 😅
I have an older Whrilpool side by side fridge and it average between 2.4 and 2.9kwh per day in the summer. We use a lot of ice and I've noticed on days we don't use much ice the power consumption is noticeably lower. It uses 186w while the compressor is on and 5w when idle. The defrost runs every 6 hours of compressor run time and last 10min. It's a 500w element which equates to around 83wh per defrost.
Another thing to think about, the way we have our thermostat set we can have a 4-6°F difference in the house between summer and winter. Just that difference in ambient temperature is enough to reduce the fridge power consumption by .5kwh in the winter.
Newer fridges use inverter driven compressors which have a much lower starting current. The older style compressors usually need 5x the running wattage to start.

I'd recommend a sample of at least a week. One day is not going to accurately project weeks, months, years. E.g. On the weekend everyone could be home opening and closing the fridge all day.

For a system that has been running for more than 6 months. My refrigerator will use 1.5 k Watts hours in a day. 1200 W of solar, 48 V 100 amp battery. Average 4 to 5 1/2 hours of sun per day. We'll run for 2 and a 1/2 days.

The more modern refridgerators/freezers are much better in power use and likely have smaller and more efficient compressors. It is often well worth replacing an older one with a newer one before you even look into solar panels and battery storage. The same for many other older appliances and of course insulation for the home. Same for hot water heating. If you can put in a hot water pre-heater to use the sun light directly for the heat then you can avoid a lot of expense and I would do this before putting in solar panels, but if you size the hot water system right and leave expansion room to add more panels then you've covered both bases.
During the last spring we had a power outage for some time and I have a battery backup unit for my computer. I was worried that some things in the freezer would not be very good if they thawed too much so after an evening of no power I took the backup unit and plugged the fridge into it. The power draw was low enough that the fridge was able to run for half an hour on what remained in the battery backup unit. The battery backup unit has a power meter built into it which told me how many watts were being used.
The most important thing was what you noted, don't open the fridge/freezer as much as possible.
Another good things to know was to have the freezer as full as possible before the power outage. So if you commonly have a lot of empty space in the freezer you can put containers of water in there to add to the thermal mass until you need the space for other things.
I cannot put up solar panels at the moment, but someday I hope to put some kind of system in.
To remove a lot of the drain of running just a refridgerator/freezer solar and battery system you could put it on a timer which would cycle only enough times during the day to run the system but would avoid some large fraction of the drain of the inverter being on continuously.

Suggestion to interested solar array / photovoltaic power seekers. When considering or setting up... consider going dc to dc when ever possible DC ACs DC fridge etc... DC powered appliances are available... going dc to dc will create an almost lossless system.

I have an upright deep freezer and a fridge freezer combo, what I have found running them 24, 7 is that both together pull around 200 watts down to 100 watts when they both are idle, but when they are running it can go as high as 600 to 800 watts likely both defrosting at the same time, but a 24 volt 200 amp hour battery was not enough to take them through the night, I had to buy another battery so now I have 24 volt 400 amp hours of storage and 2000 watts of solar, so far its been able to keep them going day and night the battery bank gets down to around 60 percent overnight so more battery is recommended. This is being home and daily use doors get opened several times a day as well.

More , the answer is always more solar and more battery s. You have to figure for cloudy days and stormy weeks.

Where I live the solar irradiance numbers are horrible in Dec/Jan. The good news is that a refrigerator isn't needed from Nov-March ;)
Another thing to consider in your numbers is if you're putting new items into the refrigerator.

Running a conventional household fridge from solar isn't the wisest use of solar in general. The compressors aren't the most efficient. I do understand the premise of your video is keeping food cold or frozen during a power outage with pre-existing refrigeration.
I can contribute information based on portable 12/24 volt compressor fridges, as have been running such from small scale solar for the last 7 years in a 12 volt system in Australia. (Apologies in advance for using amps and Amphour ratings. This is how we calculated off grid solar up until the lithium entered with "watthour" ratings. I still prefer Amphour calculations).
Was able to power 2 x Endgel fridge/freezers totalling 140 litres in capacity. A 60 litre and an 80 litre, respectively.
The average daily sun was close to 8 hours with 5 peak hours in summer in Australia, obtained by keeping the panels pointed towards the sun.
Running both as a fridge, 2 x 160 watt solar panels and 4x175AH AGM(two batteries would have sufficed) powered these two without issue in 40 celcius heat. Average power usage per day was between 30 to 40 amps combined, dependant on overnight temperature. There was amble power to spare running as fridge's.
Running the 80 litre as a freezer instead, was a different story. It required two additional 160 watt solar panels for a total of 4 to maintain the batteries in that same 40 celcius day time heat(the nights rarely dropped below 25). The 80 litre Engel was set to minus 11, which is enough to maintain frozen foods(vegtables, sausages and kfc chicken) for the 2 to 3 weeks that it was in there. Meat was placed in the bottom.
During the heat of the day the 80 litre Engel as a freezer ran continuously to maintain the minus 11 in that 40 degree heat. The compressor did not begin cycling off until roughly 9 pm. It continued to cycle on for between 40 and 50 minutes out of every hour until the internal temperature stabilised
The power usage was around 70 to 80 amps per day. Hourly current draw was between 3.5 and 4.5 amps at 12 volts.
Winter is far less of an issue here in Australia. 2 x 160 watt panels can run both, using one as a freezer.
I obtained power usage data by using inline watt meters between each fridge and the battery bank. The watt meters were for 12/24/48 volt solar/battery systems.
The advantage of a portable fridge like the Engel(popular in Australia), Bushman, Evacool, Waeco(terrible company), Companion and many other brands of varying quality and price, is they can run direct from a battery bank without an invertor in between.
This system can be operated from a power station. That route is very costly compared to a diy solar batter system of similar capacity. The 4x175AH AGM cost 1000 bucks australian. Lifepo4 of comparable capacity at 12 volts, is 2000 buck australian.
Please note, 7 years ago, AGM batteries were the best in sealed lead acid batteries for off grid solar systems. Today, these batteries have been replaced with Lifepo4 in favour of their lighter weight.

Wow. Informative. I live in Colorado and we don't have many days of cloud coverage. The southwest is ideal for solar panels.

Long term, you'll probably want to double or triple the solar panels, and make sure the power station can run the fridge for at least 24 hours in case you get a lot of cloudy days in a row.

Nice video and testing. The department of energy actually has standardized testing methods and requires a label in every fridge. Most of them come in at average 2 - 2.5 kw-hr per day.

I just did a test with a Bluetti AC180 with a single Bougerv 180 watt solar panel running my full sized fridge. I used the fridge as normal and was able to run it for 24hrs with 20% left on the Bluetti.
I don’t have much space for solar panels, so I plan to replace single 180 with 2 200w panels, then use multiple power stations, swapping them out as needed. I will eventually have 4 power stations (or extra add-on batteries) of at least 1000wh each ready for an emergency. I think this would keep me going for a while.
For now I also have a small inverter gas generator for charging the stations if too cloudy. It will also keep a small window ac going during the summer. Yeah, get a gas generator and window ac for summer and a propane heater like a Mr Heater Buddy for winter. It’s also good to have a transfer switch to easily connect your power source.

Good introductory exploration of sizing. Illinois is a reasonable testing ground, too, since their policies will make power expensive, as it is in California.
Your costs in Illinois would be good for beginners, too, especially since prices/costs are always changing.

Great video on showing really how many solar cells and size of batteries to power such a small energy usage.

I have 400w in solar, with lithium phosphate batteries, the setup is very powerful for such a small array. Technology is really moving forward.

I have a large, 12-volt refrigerator in my camper. Two lead acid batteries could not keep it running overnight. Four 200 watt solar panels and 3 lithium batteries fixed the problem.

My fridge freezer runs on 80-90 watts but pulls at least 1200 watts on start up. That's going to be very hard on inverters. I went for a victron 1200 VA unit for that reason as it's a low frequency inverter with a 2400 watt surge capacity. You can hear the transformer buzz when the fridge kicks in.

We chose a smaller fridge with manual defrost, and its only drawing 100w when running. Get sun most of the time, so 2 x 300w panels is sufficient for us.

I have been load shedding my full sized fridge with my Delta pro since Oct 2023. It snows where I am. I did have to go back on grid about a dozen times. (just for the night while I was sleeping) This spring in 2024 I added more panel wattage and two extra batteries. The rest of my house has been consuming about 76 kWh's from the grid per month. Right now they owe me just under a grand Cad on my combined power and gas bill. My 9000 watts of diy with permits solar has been harvesting 10 MWh per year since 2015. I now have an off grid array for the load shedding. It's a fun hobby.

Great info, thx! Then... in a worst case scenario being zero sun for three days, the fully charged batteries have ya covered. Day four the sun begins to shine, and now the solar panels are able to chill with zero battery. In that worst case scenario, don't I need extra solar panels that could simultaneously charge the depleted batteries to get me thru the next nite?

Back in 1994, I bought a I4.5 cubic foot cycle, defrost refrigerator with the freezer on top for $ 175.00. The refrigerator had an evaporator coil and during the off cycle the coil in the refrigerator would defrost from the ambient 38° temperature. A small resistance heater on the evaporator coil would turn on when the compressor was off to make sure it would defrost in a hot humid environment. I disconnected this heater. I insulated the outside of the Whole refrigerator and consumption dropped to 0.750 KWh a day. After 30 years, this refrigerator is still operating only to replace the start run relay and the thermostat for $ 50.00. The top freezer of this refrigerator has to be defrost 3 to 4 times a year but not the bottom refrigerator, therefore cycle defrost naturally. Refrigerators don’t last long today about seven years. By modifying this refrigerator, I probably saved over $10,000 in 30 years which translates to $30,000 when invested in an index fund. Back in 1994 I did put in a 240 watt Solar system. Used batteries, then went to Trace micro inverters.

I HAVE 4 DIY SOLAR GEN A 5000 WATT A 3000 WATT A 2500 WATT A 1000 WATT I RUN FULL TIME I LET THEM PAY FOR THEM SELF, HAVE GRID POWER IF CLOUDY DAYS COME WITH CHARGER ON THEM ALL PANELS ARE GROUND MONT ALL SO DIY BATTERYS NO BMS ONLY BATTERY BALANCER DOING GREAT , THANKS FOR ALL THE INFO

I purchased a unique 13 cubic ft fridge freezer fridge dc power. It is running on 2 battle born 100 ah batteries and 2 200 watt solar panels. 40amp victron controller. Completely off grid. Works awesome.

Using a phase change material or even just loading the unit up with some thermal mass can dramatically change how often the thing cycles.
You could probably turn the power off on the fridge for big stretches overnight using a timer, then turn it back on an hour or two before sunrise so it taps the batteries most *before* solar charging and load become available (charging is more efficient when batteries are lower than 80% or so,.and the most efficient use of solar is to run the fridge while the sun is out, avoiding the battery).

An empty unit will behave differently than a full or partially full unit. (notice I used full not empty for optimism 😊) Also how often you open the unit. Sudden load additions of warm foods will trigger slow heat exchange between the frozen or cold contents and new additions. Power use will still be affected. Saline water for frozen jugs to compensate space is a more efficient heat sink than tap water.

AMAZING INFORMATIVE INFORMATION, THANK YOU 😇👍🏾

Thanks this was a super informational video!
Could you tell me if there are any more losses associated with stepping upto 240 volts for my fridge as compared to 120V

would love to see if you numbers change if they are full of food and drinks. I am thinking the thermal mass would lower the consumption on average.

Good job with this Scott. We love our solar panels and it helps our company to be independent for the future!!

NREL has a calculator that allows you to get solar input data specific to your address, panel orientation (which way they are pointed and the angle they are mounted at. That calculator also has average weather data built into it. Yes, do use the December results if you want an adequate solar array to provide the power you need all year. You also need to take things like shading from trees into account. I am in Maine and my 1,000 watt solar array does not provide enough power to run my fridge and chest freezer in Winter. To get around that I have a 20 Kwh battery bank. Also those all in one units are terribly inefficient. I have a 4,000 watt continuous, 6,500 watt surge split phase inverter and it only consumes 18 watts at idle for 204 watt-hr per 24 hour period. Finally, when sizing your solar array for one of those all in one units be mindful of their maximum solar input. I think the maximum solar input for the Delta2 1,000 watt unit is about 500 watts.

Glad you did this. Some folks have a really warped idea that solar is some kind of miracle. Case in point the 'Solar Ferry' which appears to have about 20-30kw of solar on it. Now this is a ferry that has to fight currents, carry people and cars and do it reliably every day, on the West coast. Obviously 20-30kw equates to max 30hp motor that the solar can actively drive. Now the municipality is screwed and had to buy back their old diesel ferry. I've seen the same thing on yachts, with selling points like 'Silent Operation'..... yeah if you park it and only run the fridge. I'm not knocking solar, but a whole lot of people don't realize that his is all calculable. Top it off with losses to charge batteries, peak power etc.. 25% losses on inverters are common with similar losses on battery charging.
Point is solar is really great, but it needs to be calculated properly and it really isn't that hard. Thanks again for making this great video showing some of the pitfalls.

Soooo what was the final answer?

The Whirlpool pictured is VERY efficient (I have). It uses under 1.1Kwh per day. I had an RV fridge that consumed nearly 5Kwh/day. THAT was a drain on my 1500watts of solar. The Whirlpool effectively uses well UNDER 7% of my 15Kw battery capacity and allows me to run other systems. Now, mini-split still uses too much energy on COOL. DRY setting uses about half of COOL but I have to add electric fans to move the air around the RV. Having 2500watts or more of available solar would allow me to run the mini-split on COOL and replenish fully each day.

Just ordered the delta pro 3, looking forward to using it and maybe “saving” some money on our power bill

Cheap inverters and cheap fridges have those horrendous efficiency ratings. It might cost you an extra thousand or two to get the energy efficient models but you will certainly get the money back in run time savings.(My 26 CUFT Whirlpool fridge uses what your little chest unit does!) It was expensive up front but has repaid itself many times now in running costs, even in Houston TX where electricity is cheap.

Running an inverter can certainly kill your battery. But if you run both the Fridge/freezer and the inverter off an Arduino, it can simply turn the inverter off and on as needed when the fridge/freezer hits a certain temp. An Arduino would cost much less power to run vs the inverter all day.

I was trying to get a 12v DC/24vDC refrigerator to avoid some of the losses by cutting out the converter but those things are surprisingly expensive for their size.

Thanks, this was very easy to understand for me who has no clue about electrics.

I have a 30qt fridge/cooler that I run in my truck, and a 220wh battery lasts between 8-12 hours sitting in the seat of my hot truck in Florida, with the temp set to 37°f. If I let it run all night on that battery, it only uses about 40% on average.
I have connected a 100w foldable solar panel to it when at the beach, and that panel keeps the battery at 100% with the cooler set to 34°f. This is with the solar panel laying flat on the ground or leaning up against the cooler.

Think i will continue to plug in the wall, thanks

Awesome video. Thanks. Have you considered doing the same detailed vid on some of the newer 12V refrigerators, so that the inverters are taken out of the equation.

Thermal insulate the fridge/freezer easily 50% more efficient.
If someone is using a victron Inverter, there is a standby setting it only draws a watt or so, and awakes in (user defined) interwalls to check for a load, if there is non, it falls back to standby. Its also possible to turn an Inverter off at night. Will save even more

I enjoyed your video. I would like to see a calculation for the breakeven point for these battery systems. Thank you.

A final thought. It would probably be good to have a gas generator with a 3 day supply of gas in case the outage lasts longer than the 3 days that you'll be depending upon the battery bank especially those in the hurricane areas and maybe tornado alley. In the 40 years I've lived in AZ, I can remmember only two power outages and they lasted less than an hour each, neither caused by storms. That's not to say that we in AZ don't have storm problemss; we do and some outages do last for more than 1 day. I do have a genertator just in case.

For a 200 Wh fridge (15 minutes on) + 25Wh consuming inverter, and a 250W panel, you need one 24V 100Ah battery, if you have every day 10 hours sunlight. I have it running 6 months now and with 2 panels, I also can run my PC for 8 hours daily.
For the winter however you may need to double up 😅

My fridge runs at 37W (That's max!), as it is only a half size class C energy fridge. Average in summer is between 9 and 30W.... depends on how many liters of water I put in it to cool it. Temperatures are like 30..37 degrees celsius outside.
In the winter (have not tested yet) it would probably be on the low side of 9W average.
This is totally different from my small car coolerbox doing 56W non-stop and never being cool enough.
It is rated for 87kWh/year in normal use which I can confirm from real measurements that it probably is lower.
Class B or A full size split freezer/cooling fridges are about 120kWh/year in use.
What I am trying to say is: just upgrade your fridge. Class C is not spectacular, but I needed a cheap fridge quick.

We've been off-grid for 7 years now. The best someone can do is shop for the most efficient unit. Smaller doesn't always mean it uses less power.
Our chest freezer is 4x or 5x bigger than the one you have there and uses only 95 watts max! Not a typo, 95! I have the same plug in meter you are using to watch and measure power usage. ( That's the surge power. I was floored)
Our 55" flat screen smart TV only uses 30 watts to run . (TV was only $300 at Walmart, still operates perfectly)
Even when people come to me wanting to add/go solar to lower their electricity bill. I ALWAYS tell them to look at reducing consumption first. Even if they have to go buy new appliances to achieve it. Often spending a few $100 here or there can save several hundred in power in a year.
Also we bought 5 100 watt panels off Amazon thru the past few years for only $50-$60 each. They work GREAT!!!
They charge our 12v lighting in our house and 12v led strips in my shop.

Okay I just watched your video, and that being said, I need to point out that looking at the data plate on your fridge or freezer, and multiplying the amps times volts, does not give you the watts, which is a measurement of true power, that gives you apparent power in volt/Ampers which contains a fair amount of watt less current due to a less than perfect power factor. However, to obtain a correct reading you have to know the power factor in percent and multiply by that percentage, but the easiest way is to learn to use your "Kiii-a-Watt" meter, it has all of those measurements built-in, so if you noticed that the reading on your Kill-a-Watt meter doesn't match the watt's you get multiplying the volts × Amps, that's why, look at the va setting it should be much closer 😉

Your review is on 120v refrigerators. Aren't there 12v refrigerators available? I would like to see the same review on some 12v refrigerators. They are becoming very popular in RVs today!
Thanks for this great review!

I have a shuttle bus that I am fixing to install an 18,000 BTU mini split in. It's one of the newer model mini splits with a compressor that ramps up and down. I want to be able to power that mini split for at least three days with no sunlight. Can you recommend how much solar panels I should install on top of the bus for this? I will also have a few lithium ion batteries inside the bus as well. I plan to install a 48 Volt system with at least 4 of the 300 amp hour batteries if that's enough batteries. Thanks for any input.

Powering anything with solar is possible. The problem is the cost. When someone says they spent $10,000 to power their air conditioner it's not too impressive. When they say they spent $1,500 on a solar system to power their air conditioner then that is quite impressive. I do appreciate the education on how to add up the requirements for wattage.

The first advice I give anyone looking to use a solar system is to look for an economy refrigerator and/or freezer. I have an upright freezer that pulls around 75 Watts when it is running, and near zero, (0.4W), when on standby. My 7.5 square foot Vissani refrigerator pulls a tad over 110W, (with normal start-up being 378W), and 0.8W on standby. I understand that most people will need a larger sized refrigerator and freezer. According to data tag: Time aprox. 20m @ 86 ambient temp.; normal use:140W Defrost function: 230W

Thanks Scott. Being a complete novice at all this, I have a question. How do you get that a watt hour (wh) equals one day’s worth of power usage? I would think that something that consumes 100 watt hours would take 2400 watts in a day. What am I missing?

Great clip.
Some advices:
The newest generation of fridges, freezers,… need much less electrical power. You reduce your consumption and everything became smaller, easier and cheaper.
I checked my consumption from the main devices over one month. After such long time is each kind of usage included, no more bad surprises.
Set up to much solar panels. They are meanwhile so cheap and you will never have to much energy. But under poor weather conditions they still produce a bit. Some free electric is better than non.
Use new transformers, your devices use to much.
Regards from Belgium

I have a great way to keep my solar power exense to a minimum. I live in Alaska and we get very little light during the winter months (roughly October - March). I would need a massive amount of solar panels to satisfy the power needs of my freezer during the winter since it uses about 880 watts/day. So instead of buying a truck load of panels, I keep the freezer outside without power for most of the winter. On the few days when the temperature bumps up over 20 degrees I turn the power on to make sure everything stays frozen. I also freeze two 1-gallon milk jugs outside and put those jugs in my refrigerator to keep the refrigerator power cost down. I rotate the jugs every two days to make sure there is always a solid block of ice in the refrigerator. During summer we get lots of light and I only need a few panels to keep my LiFePO4 batteries at full charge. These little techniques don't eliminate my need for solar power entirely, but they cut the need and cost dramatically.

A more complete calculation than CHATGPT gave me. Thanks.

I'm new to this solar stuff and really love your explanations. I have a 12 year old whirlpool 26 cu.ft. fridge that states it uses 115V with a full load amp of 7.2. so that is 828 watts or 864 if I calculate using 120 V. I was wondering for efficiency purposes if I bought a 1200W 12V pure sine wave inverter with a peak surge of 2400W and connect it directly to a 12V 100ah or 200ah lithium battery if this would run my fridge. Nothing else connected to it. I experience outages about 5 or 6 times a year for several hours at most. Or do you thing I should get a 1500W inverter. Later I may get the courage to consider an mppt charger and solar panel.

Thank you for a great calculation on using just one main appliance for example. Using this calculation example, just about any other appliance can be calculated and added. How do you size the inverter to use for, say, these one or two exampled fridges?

The defrost is a heater.. so you can turn it on / off via external switch, or just manually defrost. You can also schedule defrost for noon when solar production is highest