How to build a solar PV system for RV?

Going off-grid in an RV can be a liberating experience. With an off-grid solar PV system, you can power your RV with renewable energy, reducing your carbon footprint and saving money on energy bills.

RV installed solar panels topview

However, sizing an off-grid solar PV system for an RV is not a simple task. It requires careful consideration of a number of technical factors to ensure you have the right components and capacity for your energy needs.

In this post, we’ll take a closer look at the technical details involved in sizing an off-grid solar PV system for an RV.

Step 1: Determine Your Energy Needs

The first step in sizing an off-grid solar PV system for an RV is to determine your energy needs.

This involves calculating how much electricity you need in a day. To do this, you’ll need to identify what appliances and electronics you will use, how long you will use them, and how much power they consume.

To make this process easier, you can start by categorizing your appliances and electronics into high, medium, and low power consumption groups.

High power consumption appliances include air conditioners, electric stovetops, and microwave ovens, while low power consumption appliances include LED lights, smartphones, and laptops.

Once you’ve identified your appliances and electronics, you’ll need to calculate their daily energy consumption in watt-hours (Wh). This is done by multiplying the power rating of each appliance (in watts) by the number of hours it will be used each day.

For example, if you plan to use a 100W LED light for 5 hours, the energy consumption would be 500Wh (100W x 5 hours).

Add up the energy consumption of all the items on your list to get your total energy needs for a day.

Step 2: Calculate Your Daily Solar Energy Budget

Once you know your daily energy needs, the next step is to calculate your daily solar energy budget. This is the amount of solar energy your system needs to generate each day to meet your energy needs.

The daily solar energy budget is affected by several factors, including the location of your RV, the time of year, and weather patterns in the area. In general, the amount of sunlight received by your solar panels will vary depending on the time of year and location.

For example, if you’re traveling in an area with lots of sunshine, you’ll be able to generate more solar energy than if you’re traveling in an area with lots of cloudy days.

To calculate your daily solar energy budget, you’ll need to know the wattage of your solar panels, the peak sun hours in your area, and the efficiency of your solar panels.

The peak sun hours are the number of hours per day when the sun’s intensity is strong enough to generate electricity from your solar panels.

For example, if you have 300W of solar panels and your area receives an average of 5 peak sun hours per day, your daily solar energy budget would be 1,500Wh (300W x 5 hours).

Step 3: Choose Solar Panels

Choosing solar panels is a critical step in sizing your off-grid solar PV system. You’ll need to choose solar panels that can produce the amount of energy you need each day.

Consider factors like the size of your RV and the amount of available roof space for panels.

In addition, you’ll need to consider the efficiency rating of the solar panels. Solar panel efficiency is the percentage of sunlight that is converted into usable electricity.

The higher the efficiency rating, the more energy your solar panels will be able to generate.

You’ll also need to consider the type of solar panel. There are two main types of solar panels: monocrystalline and polycrystalline.

Monocrystalline solar panels are more efficient and expensive than polycrystalline solar panels.

They are made from a single crystal of silicon and are more durable and efficient in high-temperature environments. Polycrystalline solar panels are made from multiple silicon crystals and are less efficient but more affordable than monocrystalline solar panels.

When choosing solar panels for your RV, it’s important to ensure that the total wattage of the panels matches your daily solar energy budget.

You should also ensure that the size and weight of the panels are appropriate for your RV and that they can be easily mounted on the roof.

Step 4: Select a Battery Bank

Once you have chosen solar panels, the next step is to select a battery bank that can store the energy generated by the solar panels. The type of battery, its capacity, and its discharge rate are important considerations when choosing a battery bank.

Deep-cycle batteries are a popular choice for off-grid solar PV systems, as they are designed to handle frequent and deep discharges.

Lead-acid batteries are a common type of deep-cycle battery, but lithium-ion batteries are becoming increasingly popular due to their higher efficiency, longer lifespan, and lower weight.

When selecting a battery bank, it’s important to ensure that the capacity of the battery bank is sufficient to meet your energy needs.

The capacity of a battery is measured in amp-hours (Ah) and is the amount of current the battery can supply over a certain period of time.

For example, a 100Ah battery can supply 1 amp of current for 100 hours or 2 amps of current for 50 hours.

You’ll also need to consider the discharge rate of the battery bank. The discharge rate is the rate at which the battery can supply current over time. Higher discharge rates are required for appliances and electronics with high power consumption.

Step 5: Select an Inverter

Selecting an inverter is also an important step in sizing your off-grid solar PV system. The inverter converts the DC power stored in the battery bank to AC power for use by your appliances and electronics.

When selecting an inverter, it’s important to ensure that the inverter can handle the wattage of your appliances and electronics. Inverters are rated by their maximum continuous output power, which is the maximum amount of power the inverter can supply continuously.

For example, if you have a 1,000W microwave, you’ll need an inverter that can supply at least 1,000W of continuous power.

In addition, you’ll need to consider the type of inverter. There are two main types of inverters: pure sine wave and modified sine wave.

Pure sine wave inverters are more expensive but provide a higher quality of power that is similar to grid power. Modified sine wave inverters are less expensive but can produce a lower quality of power that may not be suitable for sensitive electronics.

Step 6: Choose a Charge Controller

A charge controller regulates the charging of the battery bank by the solar panels to ensure the battery is not overcharged or undercharged.

Choose a charge controller that is compatible with your solar panels and battery bank and has the necessary features to protect your battery bank from damage.

There are two main types of charge controllers: PWM and MPPT. PWM charge controllers are less expensive but less efficient than MPPT charge controllers.

MPPT charge controllers are more expensive but can provide up to 30% more energy than PWM charge controllers.

Step 7: Design the System

Once you have all the components, it’s time to design the system by connecting the components based on their specifications.

This is a critical step, and it’s important to follow the manufacturer’s instructions and consult with a solar expert if you’re unsure about anything. The components should be connected in the following order:

  • Solar panels: Connect the solar panels to the charge controller.
  • Charge controller: Connect the charge controller to the battery bank.
  • Battery bank: Connect the battery bank to the inverter.
  • Inverter: Connect the inverter to your appliances and electronics.

Make sure to follow the wiring diagram provided by the manufacturer and use appropriately sized wiring for each component. Wiring that is too small can cause voltage drops and reduce the efficiency of your system.

Step 8: Test and Monitor

After installation, it’s important to test and monitor the system to ensure everything is working correctly and efficiently.

Start by testing each component individually to make sure it’s working as intended.

Once everything is connected, you can test the entire system to make sure it’s generating the amount of energy you need to meet your energy needs. Monitor the system regularly to ensure it’s performing optimally and troubleshoot any issues that may arise.

To monitor your off-grid solar PV system, you can use a battery monitor to keep track of the state of charge of your battery bank. You can also use a solar charge controller with a built-in display to monitor the performance of your solar panels.

In conclusion, sizing an off-grid solar PV system for an RV is a complex process that requires careful consideration of a number of technical factors.

By following the steps outlined above and consulting with a solar expert if needed, you can design a system that meets your energy needs and ensures you have a reliable source of renewable energy while on the road.

Example PV Set ups for RV systems

Example 1: 300W DIY PV Solar Power System for an RV

Materials:

  • 3x 100W flexible solar panels
  • 1x 20A PWM charge controller
  • 1x 12V deep cycle battery
  • 1x 300W pure sine wave inverter
  • Wiring
  • Mounting hardware

Combination:

  • Mount the three 100W flexible solar panels on the roof of the RV using the mounting hardware.
  • Connect the three solar panels in parallel using wiring.
  • Connect the solar panel array to the 20A PWM charge controller using wiring.
  • Connect the 12V deep cycle battery to the charge controller using wiring.
  • Connect the battery to the 300W pure sine wave inverter using wiring.
  • Connect the inverter to the RV’s electrical system using wiring.

This system uses flexible solar panels, which are more lightweight and easier to install on curved surfaces than rigid solar panels.

Example 2: 1000W DIY PV Solar Power System for an RV

Materials:

  • 10x 100W monocrystalline solar panels
  • 1x 60A MPPT charge controller
  • 6x 6V golf cart batteries
  • 1x 3000W pure sine wave inverter
  • Wiring
  • Mounting hardware

Combination:

  • Mount the ten 100W monocrystalline solar panels on the roof of the RV using the mounting hardware.
  • Connect the ten solar panels in series-parallel using wiring to create a 24V, 500W array.
  • Connect the solar panel array to the 60A MPPT charge controller using wiring.
  • Connect the six 6V golf cart batteries in series-parallel to create a 12V battery bank with 660Ah of capacity.
  • Connect the battery bank to the 3000W pure sine wave inverter using wiring.
  • Connect the inverter to the RV’s electrical system using wiring.

This system uses monocrystalline solar panels, which are more efficient than polycrystalline solar panels in low light conditions.

The 60A MPPT charge controller maximizes the efficiency of the solar panels, while the six 6V golf cart batteries connected in series-parallel provide a large capacity of 660Ah to store the solar power.

The 3000W pure sine wave inverter can power most RV appliances and electronics.