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Harnessing the power of the sun to produce electricity is a smart and sustainable way to power your home.
Installing a residential solar panel system can significantly reduce—or eliminate—your electricity bills and ensure your family’s energy security during increasingly frequent blackouts.
If you’re concerned with climate change and the future of our planet, switching to solar power is the most impactful way to reduce your household’s carbon footprint.
To chain multiple photovoltaic modules — like solar panels — in an array, you must connect them together and to your portable power station or other balance of system.
You can do that one of two ways (or a hybrid of both).
Series or parallel.
But which wiring configuration maximizes your electricity generation potential?
Read on to find out.
Wiring Solar Panels—The Basics
If you’re using more than one solar panel, connecting each PV module together and to a portable power station or other balance of system is essential.
Solar panels on their own are useless.
The magic happens when you connect a PV module to a solar inverter or charge controller to convert or store electricity.
Regardless of the manufacturer, the fundamentals of residential solar power systems stay the same…
Solar panels made up of multiple photovoltaic cells capture photons from sunlight and convert them into direct current electricity using the photovoltaic effect.
Direct current (DC) is sent via cables or wiring to an inverter, where it’s converted to Alternating Current (AC or “household”) electricity or stored in a solar battery as DC and converted to AC when discharged.
In a solar panel array, HOW you wire the PV modules together determines the essential qualities of the electricity produced.
Connecting Solar Panels in Series vs. Parallel. What Is the Difference?
In most modern solar panel arrays, the physical act of wiring multiple solar panels together is as simple as plugging in a cable.
But before you do so, there’s one essential decision to make.
Should you connect your solar panels together in series or parallel?
Or a hybrid of both?
The right answer depends on the number of PV modules, the planned layout, and your electricity generation goals.
So, what’s the difference?
- Series wiring increases the sum output voltage of a solar panel array but keeps amperage the same.
- Parallel wiring increases the sum output amperage of a solar panel array while maintaining the same voltage.
The choice you make can have a significant impact on your system’s overall performance.
For the purposes of this article, we will examine the pros and cons of series and parallel connections between solar panels of the same rated power and model.
Mixing and matching PV modules with different specs or manufacturers is possible, but it’s far more complicated than connecting multiple PV modules of the same model.
If you’re purchasing a new solar panel array, installing multiple modules of the same model will make your life significantly easier.
Before we dive deeper, it’s crucial to note:
Wiring in series or parallel determines your PV array’s combined DC output in volts and amps. Series or parallel connections do not significantly impact the total output in watts.
(Source: Alternative Energy Tutorials)
Series Wiring
To connect solar panels of the same model and rated power in series, wire the positive terminal to the negative terminal of each panel in the array.
At the end of the chain, you’ll have a single positive/negative output to plug into your balance of system.
By wiring your solar panels in series, the output voltage of the array accumulates.
In the diagram above, the output voltage of each panel is 6 volts. At the end of the series, the cumulative output is 18V (3 panels x 6V = 18V).
What’s crucial to note is that while the voltage output increases with each panel added to the series, the amperage remains the same.
Series connections are typically used for grid-tied systems that require a voltage of 24V or more.
(Source: Alternative Energy Tutorials)
Parallel Wiring
To wire solar panels in parallel, connect each panel’s positive terminals together.
You also connect all the negative terminals to one another.
Parallel wiring results in amperage accumulating and voltage remaining the same. The exact opposite effect of series wiring.
Again, using the same panels in the series example above, if the amperage per panel is 3V and you have 3 identical panels, your total output will be 9 amps (9A) and 6 volts (6V). The formula looks like this:
3A x 3 PV panels = 9A total output
Voltage doesn’t increase — the output remains 6V no matter how many solar panels you connect. If you have a 20-panel array connected in parallel with 6V/3A of rated power output, your maximum electricity production capacity is 6V/60A.
Pros and Cons
Pros of Series Connections
Voltage Accumulation: If your installation requires high voltage to operate — standard with on-grid systems — series or hybrid series/parallel wiring is probably essential. Even if it’s not, if your application is best served by higher voltage rather than amperage, a series connection is your best choice.
Efficiency and Performance: Without considering other factors, series connections will output slightly more electricity from the PV panel array than other wiring methods. Less power is lost when electricity is delivered over distance to your balance system in a series connection.
Thinner Cables: A relatively minor consideration, but parallel connections require higher gauge wiring due to how the electricity is transmitted. Series connections may cost slightly less to wire the same number of panels.
Better for Distance: Depending on the total surface area of your installation and how long the cables must be to connect to your balance of system, series connections may deliver an additional benefit. Voltage travels more efficiently than amperage over long distances.
Cons of Series Connections
Obstructions and Shade: The most significant disadvantage of wiring solar panels in series is that the output of the entire array is dependent on the individual production of each module.
If you have 20 solar panels with a rated voltage of 6V each, the maximum potential output during peak sun hours is 120V. However, if just one module is in the shade (or damaged) and only produces 4V, the array’s output will be reduced to 4V per panel. Instead of 120V of production, your panels will output 80V. If part of your installation area suffers from significant shade during peak sun hours, you should consider parallel or hybrid connections instead.
Danger: High Voltage: There are many benefits to increasing the voltage output of your solar panel array. However, high voltage can be dangerous or deadly if improperly used. Working with high voltage also dramatically increases the risk for the person doing the installation. If you decide to proceed with a series connection, it’s best to hire a professional installer.
Pros of Parallel Connections
Cumulative Increase in Current: Each PV panel you add to an array connected in parallel adds its direct current output to the system’s total output.
Less Overall Vulnerability to Shade: Unlike the voltage produced by series connections, the increased amperage (current) produced by parallel connections is not dependent on the performance of individual panels. If one PV panel is covered in shade for part of the day, the performance of the entire array is not affected. Shaded panels will contribute less current to the total output, but the maximum output of the panels receiving direct sunlight remains the same.
For example, if you have 20 panels that output 3A of current in peak sunlight, but two are covered in shade, reducing their output to 2A, the cumulative output of your array will be reduced by 2A. The total (theoretical) output is 58A instead of 60A because each shaded panel produces 1A less.
For many rooftop installations, the advantage of parallel wiring is obvious. Depending on your location and roof structure, substantial portions of your solar panel array may be regularly shaded by obstructions like trees and neighbouring buildings for part of the day.
But they may produce their full rated power at regular intervals, depending on the earth’s rotation around the sun.
If the panel’s positioning means it never or rarely gets direct sunlight, you should move it.
Solar panels still produce electricity from ambient sunlight on overcast days.
However, PV panels do not always produce their full-rated power.
Why?
PV panel performance depends entirely on the amount of solar irradiance (sunlight) it receives.
That’s why solar panels don’t “work” at night.
Investing in a mounted solar panel you know will consistently be in the shade makes little sense.
Constant Voltage: Unlike series connections, you can add additional PV panels without increasing the voltage. This makes parallel connections invaluable in applications that require 12V power input, like many motorhome and recreational vehicle systems.
Similarly, solar inverters have a maximum voltage capacity. You can add more PV panels to your array and continue using the same inverter. If you wired the same array in series and exceed the voltage capacity of your inverter, it will either shut down or permanently damage the component.
Cons of Parallel Connections
Less Efficient: The larger your solar panel array, the more power you will lose to inefficiency. Parallel wiring leaks more energy over long distances than series connections.
Less Resistant to Heat: Believe it or not, solar panels suffer in the heat. Direct sun exposure is optimal for electricity production, but solar panel efficiency declines rapidly as the temperature rises above 25°C.
That’s because the photovoltaic effect used by solar cells captures energy from sunLIGHT, not from heat.
All solar inverters and balance of system components like PWM or MPPT charge controllers have minimum voltage requirements. If heat (or other factors) hinder solar panel efficiency to the degree that voltage output decreases below the minimum requirement, adding more PV panels wired in parallel will not solve the problem.
Thicker, More Expensive Cables: Amperage (current) flows through wires in a similar way to how water flows through a hose. The more current (water) you want to output, the bigger the cable (hose) has to be. Larger gauge wires are also less efficient at moving current over long distances. Parallel connections are typically better suited to smaller installations.
(Source: Electrical Technology)
Hybrid Setups (Series-Parallel)
Connecting solar panels in series or parallel has its pros and cons.
Can you have the best of both worlds?
Yes, many large solar panel installations combine series and parallel wiring in one array to maximize the product of each group of panels.
It’s possible to strike the optimal balance between series and parallel wiring by carefully planning the wiring based on the location of the panels on the roof relative to the sun and obstacles that obstruct sunlight at certain times of day.
Typically, the goal is to achieve the right balance of producing volts and producing amps by wiring panels together in series and in parallel — not either/or.
If your residential solar installation will have more than 3 or 4 PV panels, it’s best to work with a professional installer. It will cost you more upfront but should substantially increase your return on investment and shorten your solar payback period.
For safety and performance reasons, we highly recommend that you DO NOT attempt hybrid series-parallel wiring of your solar panels on your own. Work with a reputable installer to achieve optimal results.
Some of the factors a solar power professional will consider when developing a wiring plan include.
- Desired electricity output
- Number and type of panels
- Peak sun hours at your location (how many and when)
- Direction, position, and angle of PV panels
- Any permanent obstacles to sunlight (trees and neighbouring buildings are common examples of fixed obstructions to direct sunlight)
- Average and extreme temperatures at your location
Involving an experienced installer in the process before buying your PV panels and balance of system can be an even better idea than just having them connect everything together.
The right installer can help you make an informed purchase decision and avoid common mistakes like buying too many solar panels or incompatible components.
How to Connect Solar Panels to Your Home in 7 Steps
If you’ve already purchased your solar panel array and balance of system and you’d like to install them yourself, here are seven basic steps that apply to most residential photovoltaic systems.
The instructions should be used only as a summary of the basics of connecting solar panels to each other and your balance of system installation.
For example, you should NEVER attempt to install a grid-tied system without a licensed electrician. Likewise, don’t try to connect any solar or battery-powered system to your home circuit board or existing wiring. You will likely be breaking the law, and unless you’re a licensed electrician, working with high-voltage electricity can be a fatal mistake.
Furthermore, the similarity between home integration of on-grid and off-grid solutions pretty much ends after connecting your solar panels to each other and then to an inverter.
For on-grid systems, you’ll require a licensed electrician at this point.
So, let’s focus on a more DIY off-grid solution and look at how to install the EcoFlow DELTA Pro with 4 x 400W rigid solar panels.
Step 1: Plan Your Layout
The ideal positioning and wiring for solar panel arrays is unique to every home.
Here are the essential factors to consider with an EcoFlow DELTA Pro + 4 x 400W rigid solar panels — many of which apply to any on or off-grid residential system.
- Available surface area for installation
- Average peak sunlight hours at your location
- Obstructions that will impact how much direct sunlight your PV panels receive on a daily basis
- Distance between each PV panel and the cable run from the last panel in the array to the inverter
- Ambient temperature (in South Africa, heat is the only concern)
- Direction, positioning, angle, and tilt
Step 2: Test Your Portable Power Station and Solar Panels
Unlike traditional residential solar power systems, EcoFlow’s portable power stations and solar generators have all the required balance of systems built-in, including:
- Solar inverter
- Solar battery (LiFePO4/Li-ion/Ni-Cad depending on model)
- MPPT solar charge controller
- Advanced battery management system (BMS)
Decide whether to connect your solar panels in series, parallel, or series-parallel. Parallel is often best for small systems of 2 or 3 PV panels. However, you must evaluate the optimal option for 4 x 400W rigid solar panels based on your location and other relevant conditions.
Testing your chosen configuration before installing the solar panels on your roof is essential. Preferably outside in direct sunlight. By doing so, you should avoid having to make adjustments once the panels are mounted on your roof.
With EcoFlow DELTA Pro, you can monitor how much electricity your PV panels produce on the LED display or with the EcoFlow smartphone app.
Whether you wired the panels in series, parallel, or series-parallel, they should produce between 75% – 100% of their rated power in direct early afternoon sunlight.
Remember, it’s to be expected that NO PV panel will produce 100% of its rated power at all times of day.
However, if the output is significantly less than 1600W (4 x 400W rigid solar panels), you should re-check your wiring and/or contact Ecoflow after-sales support.
Step 3: Assemble Your Mounting Hardware
EcoFlow’s rigid solar panels come with 4 x solar mounting feet. But unless your roof is perfectly angled for maximum sunlight exposure, you will need additional hardware.
You can purchase optional EcoFlow 50” Tilt Mount Brackets directly from the manufacturer’s website. The 50” (127cm) Tilt Bracket is specifically designed to make mounting your 400W rigid solar panels on a rooftop (or any other flat surface) incredibly easy.
All you need is the following tools:
- Adjustable wrench (M8 and M12)
- Tape measure
- Safety glasses
- Work gloves
If you prefer a different method of mounting your panels, such as a racking system, EcoFlow 400W rigid solar panels are designed to work easily with most third-party mounting systems.
The Tilt Bracket is simply a painless option for mounting your PV panels and positioning them optimally on your roof.
Detailed assembly instructions are included with the brackets. Anyone with even minimal DIY experience can assemble this mounting hardware.
Just be careful up on the roof!
Step 4: Mount Solar Panels on Your Roof
If you’ve opted to mount the PV panels on the roof by yourself, the first step is to ensure you have a sturdy ladder and some help.
EcoFlow 400W Solar Panels weigh 21.8kg and have dimensions of 172.2cm × 113.4cm ×3.5cm. That’s a lot of bulk for one person to carry up a ladder safely.
Using the tilt brackets will add a bit of weight but may make the panels more manageable to carry.
Once you have all four panels on the roof, arrange them in the configuration you mapped out in Step 1.
Double-check again (with the panels on the roof) that your wiring plan is correct. The panels should be as unobstructed as possible by buildings, trees, and other obstacles that regularly blot out sunlight during the day.
The surface area of each panel is approximately 1.95 m2, and you should aim to leave between 15 and 20 cm of space between each module.
Additionally, you’re advised not to mount solar panels any closer to 31cm from the edge of your roof. There may even be building code requirements for minimum distance from the roof’s edge in your location.
Given the above factors, the approximate total surface area required for installation is about 10m2, allowing for 20cm spacing between panels.
Once satisfied that your positioning is optimal, secure the tilt mounts or mounting feet to the roof according to your roof type and the instruction manual.
Step 5: Connect Solar Panels in Series or Parallel
During Step 1, you should have already decided whether you’ll benefit most from connecting your PV panels in series or parallel.
Series Connection
For series connection, connect the positive pole of one module to the negative second, third and fourth modules correspondingly. A series connection between 4 solar panels could quadruple the voltage. Amperage and wattage output remain the same.
For relatively small installations like this one, connecting the panels in series is recommended. Since the surface area required for installation is only 10m2, it’s unlikely that the performance of one solar panel will diminish the performance of the other 3 modules.
Parallel Connection
For parallel connection, please connect the positive and negative cables of one module and the second module correspondingly. A parallel connection between 4 solar panels could quadruple the amperage. Voltage and wattage output remain the same.
If you’re worried about the current being too low, consider wiring the four PV panels in parallel. With a four-panel array, there’s no benefit to wiring it in series-parallel.
Whether you opt for series or parallel, you’ll require additional cables. The exact number depends on your installation, but you’ll likely need several solar extension cables.
If you’re wiring the panels in parallel, you also need solar parallel connection cables.
Step 5: Connect Solar Panels to Your Portable Power Station (Inverter)
Once your solar panel array is connected in series or parallel, you have one final connection to make.
Using an EcoFlow Solar to XT60/XT60i Charging Cable, connect the panel closest to the EcoFlow DELTA Pro portable power station. The EcoFlow DELTA Pro is not waterproof and must be sheltered in weatherproof conditions. The XT60/XT60i Charging Cable comes in 3m and 5m lengths. If your cable run is longer than 5m, you will need an extension cable.
Remember to keep the distance between the closest panel in your array and the EcoFlow DELTA Pro as short as possible. The longer the cable, the more electricity will be lost in transmission. The shorter the connection, the more efficient it will be.
Now, just plug the XT60/XT60i charging end of the cable into your EcoFlow DELTA Pro.
Congratulations, you’re good to go.
Step 6: Test Your Residential Solar Power System for 3 Days to 1 Week
EcoFlow DELTA Pro has multiple inputs and outputs — both for charging and for directly plugging in home appliances. Inputs include AC, USB-C, DC, and Solar — you can even buy an EcoFlow EV X-Stream Adapter that allows you to power up at electrical vehicle charging stations.
Depending on your use case, connecting the EcofFlow DELTA Pro to your home circuitry is not essential, but if seamless home backup is your goal, you will want to take the next step.
Step 7: Connect Solar Panels to Your Home Circuit Board and Wiring
Integrating an EcoFlow DELTA Pro and your 400W rigid solar panels to your home circuit board and wiring is simple — for a licensed electrician.
Every step up until this point has been well within the capabilities of the average handyperson. Working with high-voltage electrical circuits is not.
Under no circumstances should you attempt to connect EcoFlow DELTA Pro to your home electrical system on your own.
You must use a licensed electrician. If you don’t, you may be breaking the law, and you’re certainly putting your life and the safety of your home at significant risk.
The good news is it’s a relatively quick job for a professional. First, you’ll need to purchase a transfer switch or EcoFlow Smart Home Panel.
A transfer switch is a device that switches a load between on-grid power and home backup power. The electrician will integrate the transfer switch with your main circuit panel. Then, you simply plug in the EcoFlow DELTA Pro for instant home backup (Transfer Time 1~2s).
A transfer switch more than gets the job done. But if you want to take control and optimization of your home backup system to the next level, consider the EcoFlow Smart Home Panel. It gives you unprecedented monitoring and control of your home backup solar power system — from anywhere with an internet connection.
When the grid is operational, you can connect up to 2 x EcoFlow DELTA Pros and get up to 3400W of fast-charging power. Adding a second EcoFlow DELTA Pro allows you to double your solar input capacity to 3200W and install up to 8 x 400W solar panels.
Remote control and extensive customization options through the EcoFlow smartphone app mean you can minimize your electricity consumption from Eskom. And — Always be prepared for load-shedding and unplanned blackouts.
Low Irradiance and Voltage Drop
Even the best solar generators can’t thrive without the proper environmental conditions. That’s why keeping your panels out of the shade and clear of obstructions (like snow) as much as possible is essential. If you are dealing with low irradiance, i.e., low light conditions, it could cause the voltage of your equipment to drop. And when it drops to a certain level, you may not be able to generate power at all.
All batteries or portable power stations require a minimum voltage to charge. The whole system is relatively useless when the panels fail to meet that minimum voltage.
Parallel-wired systems often run the risk of voltage drop. The reason is that the voltage is relatively low, to begin with, since the amperage increases, not the voltage, as you connect panels in parallel. Therefore, if conditions aren’t ideal, like in a low irradiance situation, you may swiftly be dealing with voltage drops. A hybrid or series wiring system could help solve this issue.
Additionally, you must minimize any risk of shading or low irradiance. Keeping the surface of your panels clean can also make a difference here! If shade or tree cover is unavoidable, it may be better to invest in portable solar panels rather than ones that require roof installation.
Voltage & Amps of Solar Panels Wired Series vs. Parallel
To understand why wiring PV modules in series or parallel matters, a basic grasp of what volts and amps mean in electricity is essential.
- Volts (V) measure electrical potential or force
- Amperes (amps) measure electric current.
A simple way to think about the relationship between volts and amps is to compare them to a garden hose.
Voltage is the pressure that pushes water through a hose, and amperage measures how fast the water flows.
When you wire in series, you combine the electrical pressure (voltage) of all of your panels while the rate of flow (amperage) remains constant.
On the flip side, when you wire in parallel, the amps add up, but the voltage does not.
You increase the flow rate but not the pressure.
When deciding if you’re going to wire in series or parallel, it’s essential to pay attention to the voltage and amperage of all panels and the requirements and limits of your balance of system, such as your inverter, solar battery, and charge controller.
That way, you can identify the best way to wire your array to optimize power generation without exceeding the maximum that your solar power system can handle.
Solar Panels Wiring Using a String Inverter
When shopping for a solar panel system, there are three primary types of solar inverters you may encounter.
- String inverter
- Microinverters
- Central inverters
As we’ve discussed, the voltage increases with series wiring while the current remains constant.
String inverters are designed to tolerate the high voltage produced by multiple PV modules wired in series.
Many string inverters can handle the combined output voltage of multiple series-connected solar panels at a lower cost than other inverter types.
Most residential solar panel arrays require only one string inverter.
However, using a string inverter and PV panels you connect in series can be problematic if you don’t have consistent access to unobstructed sunlight.
A string of series-wired panels is only as strong as the weakest link.
Any shade or damage that affects one of the panels drives down the efficacy of the entire array.
Additionally, be aware of the risks associated with string inverter setups.
The high voltage achieved when wiring PV modules in series makes severe electrical events — like fire or arc-faulting — more likely than with parallel connections.
Frequently Asked Questions
We know solar panel wiring can be tricky, and we’re here to help. Here are some of the most common questions, explained.
If you connect two identical solar panels together in series or parallel under laboratory conditions, the electricity output using either method will be virtually identical. Neither wiring method is “better,” only optimal for your specific application and external conditions. A hybrid series-parallel wiring plan made and executed by a professional installer is likely to yield optimal production for large residential solar installations.
Yes, you can wire solar panels in series or parallel. In some cases, you can even wire solar panels in both series and parallel simultaneously. For example, if you have two panels with 12V each, wire them in series to start. Then, assuming you have another 24V panel, you can wire them together in parallel. Assess your solar situation and how much sunlight you can access, then choose which wiring method will fit your needs the best.
The short answer is yes. Not all solar panels need to be identical to wire them effectively. However, different electrical ratings may make calculating your voltage and amps trickier. You need to be intentional about how you’re wiring to get the most out of your energy system.
If you’re wiring in series, all your panels should have the same current rating. Otherwise, the current output will only equal the lowest rating in the series. Similarly, parallel wired systems should have consistent voltage. If not, the system output will match only the lowest output rating.
If you connect solar panels from different manufacturers, compatibility is the main thing to check for. Products like the EcoFlow flexible solar panels come with universal compatibility, allowing you to create your solar set-up with existing and upgraded components.
It’s technically possible to mix 12V and 24V solar panels. But it’s not ideal. It’s best to opt for panels with as similar specs as possible. If you must use equipment with mixed power ratings, wire two 12V panels together in series before wiring them in parallel to their 24V counterpart. It’s always best to choose the wiring technique that makes the most sense for the specs of your equipment.
No. Connecting solar panels in serial or parallel does not impact how much wattage they produce in laboratory conditions. Connecting solar panels in parallel increases amperage and keeps voltage constant. Series connections produce higher voltage while maintaining amperage, regardless of how many panels you use. Depending on external factors, either method may be optimal. For large residential installations, a hybrid serial-parallel wiring plan is often best.
Yes. As long as you don’t exceed the maximum solar input of your portable power station, solar inverter, or solar battery charge controller, you can add more solar panels to meet your electricity production needs. It’s common for people to underestimate their electricity consumption. If you think it’s likely that you’ll want to add to your PV array as time passes, opt for a balance of system with sufficient capacity to accommodate growth.
Yes. If you have more than one 12V panel, you can connect them in series to combine their output voltage. When you wire in series, you add the voltage of each panel together. If you connect 2 x 12V panels, you get a total output voltage of 24V. Make sure the combined voltage doesn’t exceed the maximum input capacity of your solar inverter or charge controller.
In small systems, e.g., two solar panels and a portable power station for an RV, connecting panels in parallel will likely result in slightly faster recharge times. A series or a hybrid of series-parallel connections might be optimal for whole-home battery backup. Which wiring method provides the shortest charging time for solar batteries is not dependent on whether it’s series or parallel – it’s dependent on external factors.
When wiring multiple photovoltaic modules together, it’s essential to consider the specs of each panel. You can solar wire in series, parallel, or a hybrid configuration of both to achieve optimal results. When you wire in series, you add the voltages together. When you wire in parallel, you combine the amps.
Bottom Line
With solar energy costs rapidly decreasing, renewable energy technology is now accessible to almost everyone.
That’s excellent news if you care about the climate crisis and want more autonomy over how you power your home.
Take the time to plan and optimize your solar panel connections to get the most bang for your buck.
Both parallel and series wiring methods have their perks and drawbacks.
Sometimes, hybrid wiring is the best choice — especially for larger PV arrays.
Choose wisely!
The right decision brings you one step closer to energy independence.