Calculating Solar Power Requirements for an RV Air Conditioner
Generally, an RV air conditioner rates 13500 to 15000 BTUs and requires 1/1.5 kW energy for one hour to function. You can calculate the solar power needed for your RV air conditioner by getting the size of your RV electrical system in kilowatts. And multiplying the size by 1000 (Remember 1000 Watts makes 1 kilowatt).
Size of RV plug supply x 1000 = solar power needs
With an AC unit calculator, you can calculate the amount of solar power required for your AC and know how many panels can achieve it.
It is achievable to run your air conditioner on solar. You just need more knowledge of an RV AC's energy consumption and power usage before running it. Additionally, you would need a solar panel, a solar charge controller, a battery bank, and an inverter when installing solar for an RV air conditioner.
Learn more about these necessary components and how to calculate each accurately for optimal operation and comfortability.
Although solar energy is frequently referred to as an "unlimited power source," actually using solar energy remains slightly challenging.
Since you are researching solar power for your RV, learning about solar energy's pros and cons is essential.
Solar inverters, panels, and batteries are the major components you must properly size as part of a system to power RV air conditioning.
Solar panels automatically solve the power supply problem for your RV AC. The panels can generate enough power or electricity with the perfect angle and abundant direct sunlight.
Your inverter must be large enough to accommodate both the starting power and running power of your AC appliances. Solar energy generated by your panels and stored in your battery is converted into AC power by inverters. An inverter is highly required to power the common devices found in an RV, such as TVs and air conditioners.
Your battery bank is essential for your RV's AC system to operate. The more solar panels you have, the more energy your batteries can store. Nevertheless, the electricity is wasted if your batteries can't hold all the power the panels generate. For this reason, it's crucial to have a battery bank that is big enough to supply an AC unit with all the energy it requires.
To provide sufficient power for an RV AC, you must know the electricity amount your exact RV needs.
Selecting the right size of panels, batteries, and inverter to meet those electrical requirements is very significant.
Most RVs are designed with a quality AC unit with a 13,500 BTUs ranking. However, there are some RVs with larger Air Conditioning units ranking higher.
With an RV panel LED display, you can simply turn on your AC unit while reading the displays.
Dividing the daily energy consumption of your air conditioner by the number of peak sun hours you receive each day will help you determine how many solar panels you need to get the approximate amount of solar electricity.
Let's imagine, for instance, that you want to operate your air conditioner for three hours every day, and it uses 1.2 kWh of energy per hour. As a result, your air conditioner will use 3.6 kWh (3600 Wh) every day.
With this information, you can calculate the size of the system that you need:
Panel Rating (W) = power consumption (Wh) ÷ Highest Sun Hours
Panel Rating (W) = 3600 Wh ÷ 5.86
Panel Rating (W) = 614.33 Watts
So, to be able to run your RV AC for three hours every day, you need panels that are about 600 watts in size. 6 RV solar panels with a 100 Watt rating or two home solar panels with a 300 Watt rating each would make up such a system.
Also, you need a battery bank to give the AC the power it requires and access to the energy generated by the solar panels.
Although estimating battery banks require some sophisticated calculations, it's a crucial step in determining the size of your solar project.
You require an additional 150 Ah of capacity for every hour that you intend to run your Air Conditioner when the sun isn't shining directly on your solar panels with this 150 amp A/C unit.
So, the length in which your AC runs on overcast days or in the evenings depends on the size of your battery bank.
The DC-to-AC inverter is another crucial factor in your solar project. The initial wattage of your solar power system will significantly impact the size of your inverter.
The initial power of 13,500 BTU air conditioners ranges from 2800 to 3000 watts. It's detrimental to max out an inverter each time you are on the air conditioning system.
So, it would be best to look for an RV inverter of at least 3500 or 4000 watts. Naturally, this number will be higher if you have a larger air conditioner that needs a higher initial wattage.
According to the manufacturer, a typical solar panel, when installed on the roof space of your RV, produces between 100 -160 watts. While in the sun for up to 9 hours, a 100-watt panel may produce 30 Ah of battery electricity. A 12-volt lead-acid battery also has a capacity of roughly 100 Ah.
As a result, you need at least three to four solar panels if you wish to charge a 100 Ah 12-volt battery in your RV. Each solar panel produces roughly 30 Ah. But, because of how they are installed, your RV solar panels may not always receive the best sunshine exposure.
An average RV air conditioner normally uses 1 to 1.5 kWh of electricity per hour and is rated at 13500 or 15000 BTUs. Some RVs have two air conditioners, which would use two times the amount of electricity to operate.
So, you would need to install a minimum of 1,728 watts of solar panels to maintain the level of operation of the 13,500 BTU A/C unit in your RV (120 amps x 14.4 volts = 1,728 watts).
Generally, the RV air conditioner has lower power consumption compared to other solar-powered air conditioners. A 13500 to 15000 BTUs RV AC requires 1-1.5 kW energy for an hour to run. Also, the higher the AC BTUs, the higher the power required.
Furthermore, solar batteries (battery banks), solar panels, and inverters are all essential components for solar installation. And you have to get the right sizing for your RV AC to run properly.
With 100 Ah of energy storage, you need 300 watts of power to run your AC in an RV. If you have two combinations of batteries that are up to 200 or 250 Amp Hours, your panel output must be less than 600 watts.
Yes, there is! First, get the size of your RV electrical system in kilowatts. Multiply the size you need in KW by 1000 to get the system's size in watts. Remember, 1000 Watts makes 1 kilowatt.
Size of RV plug supply x 1000 =?
BTU, meaning a British thermal unit, is used for the measurement of thermal energy. This measurement indicates how many BTUs per hour the unit can add or remove the air in heating and cooling applications.
Renewability Decrease of reliance on the electric grid Electrical application utility Requires little maintenance Expensive initial setup Dependent on cloud cover Expensive and inefficient battery storage