Off-Grid Inverter Buyer’s Guide

Living or working off-grid means you are responsible for all your own energy needs—you produce, store, and process every kilowatt-hour you consume. One part of that processing is converting the DC energy in your batteries to AC energy for use in standard AC appliances. This conversion is accomplished with an inverter.

There are several off-grid (a.k.a. “stand-alone” or “remote”) inverters to choose from. Modern inverters are reliable, quiet, and come in a variety of sizes. This article will help demystify the inverter selection process so you can choose an inverter that is appropriate for your needs. We have restricted our list to residential-sized inverters (those that produce 1 to 6 kW), but the same process applies to larger systems. Only inverters that meet Underwriters Laboratories (UL) 1741 standards, as tested by a recognized certifying agency, are included in the list.


All of the specifications listed in the table were provided by the manufacturers. Note that some published specifications are not third-party verified, i.e., by UL or an equivalent testing agency, and there have been instances in the past when some manufacturers published incorrect values—like the no-load draw, for example.

One “spec” that is not shown in the table is a comparison of how long each inverter has been in the field. This can be important since it is possible that newer models have not had sufficient testing prior to release. Also, new equipment may have software bugs or integration issues that might not yet have been discovered—which may make you an unintentional beta-tester. So if you are on the fence between two choices of inverters, you might consider how long the inverters and companies have been around before you make your decision.

Waveform (sine wave vs. modified sine wave). Modern off-grid inverters are sold with two waveform options: sine wave and modified sine wave (sometimes called “modified square wave”). Sine wave output, which has low total harmonic distortion, will power virtually any type of load, even sensitive audio electronics. Although almost all residential inverters have sine wave output, a couple of modified sine wave inverters made our list for budget systems. For instance, a typical 2,800-watt sine wave inverter costs about $2,100, while a modified sine wave inverter with the same output retails for about $1,500. However, modified sine wave inverters may not run some types of loads satisfactorily, and some loads won’t run at all.

Total harmonic distortion (THD) is the measure of how closely the waveform matches a perfect sine wave. Glitches, transients, harmonics, spikes, and distortion all describe alterations to the waveform shape. Inverter electronics produce steps to approximate a true sine wave—the greater the number of steps, the less THD an inverter will have.

A THD of 0% is a perfect sine wave, and the larger the percentage, the farther it deviates from a sinusoidal waveform. Sine wave inverters typically show a THD of 5% or less, while the THD of modified sine wave inverters may range from 10% to 40%. Because THD for modified sine wave inverters varies and depends on the type of loads running, values given from manufacturers are hard to compare fairly, so these numbers are not listed for modified sine wave inverters.

It is important to note that grid electricity also can have waveform distortions due to activity from all the different loads on the grid (such as large motors starting), which can cause transients in the utility waveform. Because of this continual variation of grid activity, sine wave inverters often have even less THD than grid electricity.

Rated Continuous Output Power. An off-grid inverter must supply enough power to meet the needs of all the appliances running simultaneously. Before selecting an inverter, you must know the loads you will power—and their power and surge needs.

Sizing an inverter for an off-grid system, which is based on instantaneous load, is very different from sizing a grid-direct inverter, which is determined by the RE power source (i.e., PV array watts). A grid-direct inverter’s job is simply to convert all the DC from the PV array into AC power, which is fed back into the house electrical system—then onto the grid if production exceeds household energy consumption. In a grid-direct system, the inverter is not responsible for meeting the AC loads, since practically unlimited utility power is available. For example, a 2,000 W grid-direct PV system would require choosing an inverter that accepts 2,000 W of PV on its DC input.

In the case of an off-grid system, the inverter is usually responsible for providing energy to all the AC loads. Say you need to simultaneously power 2,000 W of AC loads. For an off-grid system, you’d need an inverter that could supply at least that amount. Note that the PV array size does not enter into this inverter sizing.

Nominal Battery Voltage(s). Each inverter has a nominal battery voltage that it can be connected to. Common off-grid inverter battery voltage options are 12, 24, or 48 volts.

Smaller systems are typically matched with lower power inverters and lower battery voltages. The converse is true for bigger systems. For example, several 2,000 W inverters have a 12 V nominal battery bank voltage; 4,000 W models generally have 24 or 48 V battery bank voltages; and 5,000 W units are typically matched to 48 V battery banks only.

For the same power, higher nominal battery bank voltage means lower amps (watts ÷ volts = amps) in the battery cables—which translates to less energy loss for the same-sized cables, or smaller-diameter, less expensive cables and smaller overcurrent protection for those cables.

Output Voltage. Most off-grid inverters have 120 V output, although some have 120/240 V output, which allows the inverter to power both 120 V and 240 V loads. Inverters with 120/240 V output cannot supply all their output on one leg. They are usually derated by 75% or so for single leg (120 V) output only. To maximize performance, be sure to balance the loads on both legs when running 120 V loads. Inverters with 120/240 V input also can accept both legs of a 240 VAC generator, enabling you to get maximum capacity for battery charging with a single inverter.

Peak Surge. Some loads (like motors) require significantly more power during startup than they need to run. To start these loads, inverters will briefly “surge” or run at higher than their continuous power rating. Surge ratings include the maximum amperage and a time period that the inverter can run at that high power level without sustaining damage or turning off to protect itself.

Inverters may have several surge ratings (stated in either AC amps or watts), each corresponding to a specified time period. Most load surge happens in the first few milliseconds of startup. For inverters with several surge ratings, generally it is fine to consider the shortest one. Typically, this is the rating you would use to determine if the inverter can supply enough power for your surges. If in doubt, talk to the inverter manufacturer to make sure the unit can supply the surge capability you need.

Loads with induction motors, like washing machines, pumps, and power tools, can have large startup surges—up to seven times the running wattage. Look for “VA” on the nameplate, “locked-rotor amps,” or “surge rating” for clues that the load may have a high surge. To determine the surge of a particular appliance, either measure the load’s maximum amps with a recording clamp-on ammeter, look for “start amps” in the specification sheet, or call the appliance manufacturer.

Stackability. Some off-grid inverters include the capability to connect several units together to operate as a single, larger unit. Various stacking options allow 120 V inverters to work together to power 240 V loads (such as well pumps). These inverter configurations can accept both 120 V legs of a 240 VAC generator, allowing for full usage and balancing of the AC generator output, just like a single inverter with a 120/240 V output is capable of.

Stacking setups can allow one inverter to “sleep” while power needs are low, which helps reduce standby energy loss. Series stacking 120 V inverters means that the inverters have a 120/240 V output from two inverters. Parallel stacking two inverters means the inverters will output 120 V at double the amps of a single inverter. Some inverters can be stacked to supply three-phase power, often used for heavier machinery.

Some inverters have a 120/240 V output available from a single inverter, so series stacking is not necessary. They can be stacked in parallel to offer more capacity (higher amps).

Inverter Peak Efficiency. Efficiency is measured as the ratio of the inverter’s AC power output to the DC power input from the batteries. Higher efficiency means that the inverter wastes less power while converting DC into AC.

Note that “peak” efficiency doesn’t necessarily represent actual operating efficiency, which changes with the size of the AC loading on the inverter. Peak efficiency is typically reached at about two-thirds of the inverter’s continuous output rating, and decreases as the continuous output rating is approached. Most inverter manufacturers publish efficiency curves in their documentation. It is wise to choose inverters that have high efficiency ratings across a wide range of output wattages.

No-Load Draw. This is the power used by the inverter just to keep running when there is no load. No-load draw can be surprisingly high in some models (up to 30 W). Since there may be long periods of time when no power is required by the loads, this can add up to a substantial energy drain on the system. For instance, an inverter with a 30 W no-load draw will consume a minimum of 720 Wh daily. On small systems, this load can have a significant impact, especially in the winter when solar-made energy is at a premium.

Search Power. Most off-grid inverters have a power-saving feature called “search” or “sleep” mode to power down the high-energy-use components of the inverter when there are no loads on. Search mode also requires power, but much less than the no-load draw. In this mode, the inverter periodically tests the circuit for active loads and powers up only if a load is detected. But homes that have continuously running AC loads (like a telephone answering machine’s 2 W wall cube) are unable to take advantage of this feature and are stuck with a minimum of the no-load draw. Some off-grid homeowners will strive for always-on loads to be DC-powered to allow their inverters to spend more time in energy-conserving search mode.

Battery Charger. Many off-grid inverters have an integrated battery charger that can be used to charge the batteries from an AC source, such as an engine generator. This feature negates the need for a separate external battery charger. Having an integrated charger is especially helpful during periods when an RE power source cannot keep up with household loads, such as during the short and often cloudy days of winter. The battery charger is also used to “equalize” batteries by giving them a controlled overcharge, making sure that even the weakest battery cells are occasionally brought up to full.

Chargers are usually rated in DC amps, but may be stated as AC amps, so read the documentation carefully. In the table, AC battery charger maximum current has been converted to DC amps.

Battery Temperature Sensor. The internal resistance of a battery increases as temperatures drop and decreases as temperatures rise, affecting battery voltage. At a given charge rate, at low temperatures batteries can get undercharged and at high temperatures they can get overcharged. To properly charge batteries where the temperature strays from the ideal 77°F, a temperature sensor provides data to the charger so it can adjust the voltage set points for higher and lower temperatures.

Generator Start. Some inverters can start and stop a generator based on several criteria, such as battery voltage, battery state of charge (SOC), load draw, and time of day. Generators can have either a “two-wire” or “three-wire” start mechanism. A two-wire start refers to two positions—on and off—and requires only a simple relay and a signal from a controller in the inverter/charger.

A three-wire start—a crank position, run, and stop—is more complex. There may also be pre-crank and other settings, as needed for diesel engines. Facilitating a three-wire start usually requires a separate controller from the generator manufacturer. Typically, inverters that advertise automatic generator start can be assumed to provide only the signal for a two-wire start.

Metering. Several inverters offer metering as an optional accessory. Metering can provide helpful information about the system, including battery voltage (lets you know if the battery is being charged or discharged), AC load amps (indicates the size of the AC loads), battery charging amps (from the AC power source), and even error codes (helpful for inverter troubleshooting).

With programmable inverters, the meter is often also a user interface for controlling other functions, such as turning the inverter on/off, starting a generator, or adjusting battery charger settings.

Remote Display. Usually the inverter is installed away from living spaces, and remote metering allows users to easily monitor their systems from a location away from the balance-of-system components. Often, remote displays show various other system metering details and have a switch to shut off the inverter. Aftermarket meters are available that can supplement the information available, like provide accurate battery SOC readings.

Integrated System Components Available. Some inverters can be part of packaged systems to ensure that individual parts—such as metering, charge controllers, and circuit breaker/disconnect boxes—work together and physically fit together.

Integrated system components offer a few advantages. First, the unit is engineered so the components fit together easily. Second, proper wire sizes are accommodated in appropriately sized boxes, and knockout holes that match up in the boxes and components. Often, a mounting plate that supports the whole system and provides the layout for the components is included. These systems can be prewired by the factory or distributor to meet the specific needs of an installation—all the installer needs to do to the integrated components is properly wire the inputs and outputs.

Electronic and communications integration can optimize operations such as battery charging and load support, eliminate the duplication of sensors (such as battery temperature sensors for both charge controllers and inverters), and provide a means for external data collection. A central control/meter can display system settings and data values, and simplify the user interface. Operations like generator start-and-stop controls can easily access needed parameters and data values, such as PV input, loads, and battery SOC.

Weight. Most of the weight of an off-grid inverter comes from the iron core transformer, which gives high surge capacity—an iron core can store energy for a few cycles, creating a flywheel effect to carry the inverter through surges.

If you are running only small electronics that have negligible surges, a lightweight inverter may serve you well. For instance, our PH1800 inverters are very light, so they don’t provide much surge capacity—yet they have a very fine waveform for finicky electronics, such as audio or telecommunications equipment.

If you are powering loads with high surges, like induction motors, seek a heavier inverter—and ensure that it is securely mounted to support its weight.

Warranty. Off-grid inverters are warranted against defects in materials and workmanship for up to one year, and extended warranties are sometimes available. Inverter manufacturers are typically quite responsive to addressing inverter failure and malfunction. Your installer or dealer can help with warranty problems and will be the initial contact.