What Size DC to DC Charger Do I Need? A Step-By- ...

Are you currently working on your camper and wondering what size DC to DC charger you need? Look no further, as we have some insights that might be helpful for you. 

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In this blog post, we will discuss the important factors to consider when selecting a DC to DC charger for your camper to efficiently charge your campervan battery.

Choosing a charger that fits within the maximum current limit is a safe way to ensure your battery and alternator remain healthy. However, including the practical elements like usage and lifestyle will ensure optimum output from your DC to DC battery charger.

By the end of this post, you’ll have a better understanding of what size DC to DC charger is best suited for your needs.

Let’s get started!

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Trust Me, I’m An Electrician

Jolly is a self-confessed electrical geek with over 17 years of experience as a qualified electrician and electrical engineer.

His focus now is campervan conversion electrics which started in 2019 with the birth of Vandercamp. Jolly is either building his own campervan or providing electrical help and guidance to others.

The Renogy 40A DC to DC charger is installed on his current campervan powering a Renogy 200Ah Lithium Leisure battery. 

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Calculators

Here are five, easy to use, calculators to help you determine what size DC to DC charger you need. They do the hard work for you. So, find the calculators throughout the guide or jump to which one you need.

What is a DC to DC Battery Charger?

A DC to DC battery charger (also known as a battery to battery or B2B charger) is a clever device that sits between the starter (vehicle) battery and the leisure (house) battery. The starter battery supplies power to the engine and vehicle electrics, whereas the leisure battery powers the campervan electrics (lights, sockets, fridge, heater, water pump etc.).

While the engine is running, the alternator charges the starter battery. The same charge current is converted by the DC-DC charger to ensure the leisure battery receives optimal charging.

DC-DC chargers are clever because they adjust their charge voltage based on the type of battery (Lithium, AGM, GEL) it’s charging. 

Additionally, when the alternator is not providing any charge current, the DC-DC charger will separate the leisure battery from the starter battery to prevent the starter battery from draining.

Further Reading | Discover 4 Other Ways Of Charging A Campervan Leisure Battery

Is A Bigger DC to DC Charger Better?

To clarify, by ‘bigger’, we mean the output charge current. So, is a higher output charge current better than a lower output charge current?

The obvious answer is yes because a higher charge current will charge the leisure battery faster. So why would you need a lower charge current?

Why bigger is better

• Faster battery charging (More charge current flow into the battery)

• For powering a load as well as charging the battery (e.g. fridge)

• Large battery banks

• Higher solar input capabilities for DC-DC + Solar chargers

Why bigger is not better

• They’re bigger, so more space is required to install them.

• More expensive (Charger, wiring and fuses)

• Bigger input and output cables are more difficult to route and install.

• Charge current is limited by the maximum charge capacity of the leisure battery

• More stress on the alternator (compromise charging and alternator lifespan)

• Heavier.

Determine the maximum DC to DC charge current for your camper (3 things to consider)

To determine what size DC to DC charger you need, you need to know these three things from your campervan electrical system:

1. Alternator and starter battery voltage (V)

2. Alternator output current (A)

3. Leisure battery maximum charge current (Ah)

By understanding these figures, you can determine the maximum DC to DC charge current that can be used in your campervan’s electrical system. Then we can move onto the other, more practical, factors to consider.

Once you know these figures, we show you how to determine the maximum DC-DC charge current for your campervan by using our simple DC-DC charger size calculator below.

Alternator And Starter Battery Voltage

Campervans typically use 12 or 24 volt DC electrical systems.

When setting up your campervan electrical system, check whether your vehicle has a 12-volt or 24-volt alternator and starter battery. This will help you choose the appropriate DC to DC battery charger.

The best DC to DC battery chargers for campervans are all 12 volts. 24 volt chargers are available, but the selection is limited.

How To

How To – Test The Alternator And Starter Battery Voltage

1. Start the engine
2. Use a voltmeter set to read DC voltage.
3. Test the starter battery voltage by putting the negative (black) probe onto the ground terminal (Black/-) and the positive (red) probe onto the positive terminal (red/+).
4. Check the voltage reading on the voltmeter

12v systems = The charge voltage should be slightly higher than 12 volts. Approximately 13.5v-14.5v.

24v systems = The charge voltage should be slightly higher than 24 volts. Approximately 28.8v-29.4v

Alternator Output Current

The output current of an alternator is measured in amp hours (Ah). A percentage of this current charges the starter battery, which powers the vehicle’s electrics.

Alternators come in many sizes, depending on the engine and vehicle size. As a general guide;

• Standard vans have alternators rated at 70-120Ah
• Larger vans and commercial vehicles have alternators rated at 120-180Ah

It’s important to ensure a DC to DC charger does not exceed 50% of the alternator’s output current (Ah). This will prevent the alternator from overloading (which could reduce its lifespan and burn it out).

For Example, if the alternator is rated at 90Ah, the DC-DC charger should not exceed 45 amps.

Additionally, during start-up, a DC-DC battery charger can draw up to 50% more current from the alternator than the rated current. 

For Example, a 40 amp Renogy DC-DC charger could draw up to 60 amps of power during start-up.

Therefore, without this 50% rule, it would be easy to overload an alternator.

How To

How to – Find Your Alternators Output Current

Determining the output current of your alternator can be tricky. Luckily, alternators typically have a stamp with a part number and amperage. However, alternators are mounted to the engine, so they aren’t easily accessible and are usually covered in oil and engine guck. 

If the amperage isn’t legible, a search on Google with the part number will give you the amperage of the alternator. Even though it’s tricky, this is the best method because it’s the most accurate.

The easiest and cleanest way is to search for your vehicle’s alternator using an online parts specialist like Euro Car Parts. Just pop in your registration to see the parts for your vehicle. However, vehicles have different models with different size alternators, which is less accurate than the previous method. If you use this method, always opt for the lowest Ah-rated alternator to be safe. Also, it could be a gamble if the previous owner has installed an aftermarket alternator.

Alternatively, use a mechanic who will easily identify what alternator you have.

Leisure Battery Maximum Charge Current

Find the maximum charge current a DC-DC charger can deliver to your leisure battery.

There are different types of leisure batteries; open & closed-cell lead-acid, GEL, AGM and Lithium, each with their own charging characteristics.

A battery’s type and capacity (Ah) will determine the maximum charge current it will allow. Exceeding the maximum charge current will damage the battery. 

As a general rule:

Battery TypeMax. Charge CurrentE.g. 100Ah Battery Sealed Lead-Acid30%30Ah AGM30%30Ah GEL50%50Ah Lithium-ion50%50Ah

A battery’s maximum charge current can also be found in its specification (online or in the manual). 

Renogy 200Ah lithium battery maximum charge current taken from the user manual

How To Determine The Maximum Charge Current

Now you know the alternator and battery voltage, alternator charge current and maximum battery charge current, use Calculator #1 below to determine the maximum size DC to DC battery charger for your campervan.

Calculator #1

Maximum DC To DC Charge Current

Alternator Output Current (Amps)

Maximum charge current <50% of amp rating

Leisure Battery Type

Leisure Battery Capacity (Ah)

Battery Maximum Charge Current

Amps

Maximum Charge Current Your Electrical System Will Allow

Amps

Maximum Size DC To DC Battery Charger For Your Campervan

Amps

DC-DC chargers have fixed output currents. Therefore, the max. charge current is rounded down to the nearest 10.

Other things to consider

Many factors will affect what size DC to DC charger is best. Of course, campervans have varying requirements and needs, so here are other factors to consider.

Usable battery capacity

To keep a battery healthy, you need to know its usable capacity (the amount of stored power that can be accessed). 

It’s important to note that even if a battery is rated at 100Ah, you may not be able to access all that power. The usable capacity of a battery depends on its type. Typically,

Lead-Acid = 50% usable capacity

AGM = 80% usable capacity

Lithium = 95% usable capacity

For Example, a 100Ah lead-acid battery’s usable capacity is 50Ah (50% of 100Ah = 50A). Whereas, a 100Ah lithium battery’s usable capacity is 95Ah (95% of 100Ah = 95A)

Discharging a leisure battery past its usable capacity will significantly affect its health and lifespan. 

Calculator #2

Usable Battery Capacity

Battery Type

*

Battery Capacity (Ah)

Usable Battery Capacity

Ah

Battery Recharge Time

Ideally, we want our leisure battery fully charged when we reach our destination, right?

So, providing we know the maximum DC-DC charge current for our campervan electrical system and the usable capacity of the leisure battery, we can work out the recharge time of the leisure battery and how long you need to drive until the battery is fully charged.

Usable Capacity ÷ Max Charge Current = Battery Recharge Time

Calculator #3

Battery Recharge Time

Usable Battery Capacity (Ah)

See Calculator #2

Maximum Charge Current

See Calculator #1

Recharge Time (Hrs) From 0 - 100%

Hours

To Recharge The Battery By 100%

Recharge Time (Hrs) From 50% - 100%

Hours

To Recharge The Battery by 50%

Recharge Time (Hrs) From 80% to 100%

Hours

To Recharge The Battery by 20%

NOTE: These results are basic recharge time figures. Other factors will effect the recharge time so please take these results as a guide.

For Example, A 200Ah lithium battery has a usable capacity of 190Ah (95%). The maximum charge current of the electrical system is 75 amps. Therefore, it will take 2.5 hours to recharge the battery from empty (190Ah / 75A = 2.5 Hrs)

This example shows it will take approximately 2.5 hours to fully recharge a 200Ah leisure battery using a 75 amp charge current. However, a 75A DC-DC charger doesn’t exist, so you would need a 70 amp charger or less. As a result, the recharge time would increase to 2.7 hours (190Ah / 70A = 2.7 Hrs).

Powering a load while driving

The joy of having a DC to DC charger is you can charge your stuff on the move; when you reach your destination, the beer’s cold and everything’s charged.

However, using power while driving will reduce the charge current to the leisure battery.

If you want to learn more, please visit our website Ground Mounted Dc Charger.

Further reading:
Which companies offer Ev Charger Odm/Oem services?

For Example, while driving, you may need to power a fridge and charge a phone/camera – a total power consumption of 10 amps. If your charger is rated at 40A, the remaining charge current to the battery will be 30A. Less charge current will mean you’ll need longer to charge your battery.

Comparison of Single-Phase and Three Phase Solar ...

Alternatively, if you require 40A of charge current to the battery and have a driving load of 10A, you will need a DC-DC charger rated at 50A (40+10 =50).

Note: These figures are an example. The charge current you need may be restricted by the alternator’s output current and the battery’s maximum charge current.

How To

How to – Calculate Your Power Consumption While Driving

1) Determine what you may need to power whilst driving.

Example – Fridge, phone x2, camera battery

2) For each appliance, determine its watt/amp rating (sticker/stamp on the appliance or adaptor plug socket).

Example – Fridge 150w, phones 3A, camera battery 1.3A

3) If it’s stated in Watts, use this formula and calculator to convert Watts to Amps. Watts/Voltage = Amps

Example – Fridge – 150 watts/12 volts=12.5 amps

Watts

Volts

Amps

A

4) Add up all the appliance’s Amp ratings. This is your total amount of consumption per hour (Ah). However, this is the worst-case scenario because you’ll unlikely need to charge all appliances simultaneously. Additionally, appliances don’t use 100% of their energy (e.g. fridges turn on/off to keep the temperature constant, and phone chargers only use energy while the phone is charging)

Example – Total= 12.5 + 3 + 1.3 = 16.8Ah.

5) Deduct your total Ah usage from the DC-DC charger output amp rating.

Example – 16.8Ah -40A = 23.2Amps

Therefore, 23.2 amps is the lowest (worst case) charge current the leisure battery will receive from the charger.

Calculator #4

Powering A Load While Driving

If the appliance is rated in Watts (W). Use this calculator to convert Watts to Amps.

Watts

Volts

Amps

A

Journey Time (Hours)

DC to DC Charger Current (Amps)

Appliance 1

Amps 1

Ah 1

Appliance 2

Amps 2

Ah 2

Appliance 3

Amps 3

Ah 3

Appliance 4

Amps 4

Ah 4

Maximum Total Ah Power Used While Driving

Ah

Charge Current To The Battery While Powering A Load

Ah

Factoring in the power consumption while you drive will ensure you have optimum battery charging.

Budget

The Renogy DC-DC battery charger is the best value charger for any campervan conversion. It’s much cheaper than its rivals without compromising on quality and efficiency. Check out our full review and comparison table.

However, if you don’t have a strict budget, there is a wide range of campervan DC-DC battery chargers. Our post on the best DC to DC battery chargers for campers compares the top 5 chargers, including their cost, so you’ll be sure to find one that suits your budget.

Dimensions

The size of campervan electrical components is sometimes overlooked, especially when choosing what size DC-DC charger you need.

If you are limited on space, factoring in the dimensions is crucial to ensure you have enough space to install it AND enough space for the cables and airflow.

Additionally, a DC-DC charger must be installed near the leisure battery to reduce voltage drop. This will ensure the battery receives the full output current from the charger. 

NOTE

What Is Voltage Drop?

Voltage drop is the amount of voltage that is lost in an electrical circuit. It occurs when the voltage at the end of a cable is less than at the beginning.

Therefore, the longer the cable, the more voltage drop. 

So, if the cable from the DC-DC charger to the battery has voltage drop, the battery may not get the charge voltage it needs.

Here are the dimensions for the best campervan DC to DC battery chargers;

The complete comparison table can be found here.

Future proofing

Do you plan to upgrade your campervan electrics in the future? Maybe to increase the battery capacity or upgrade to lithium? Future-proofing is worth considering when calculating what size DC to DC charger you need.

Whether it’s increasing the battery capacity or changing the type of battery, DC-DC chargers are compatible with all campervan leisure battery types. But will the output current be enough when you upgrade?

For Example, you may be increasing your battery capacity, so you need 30 amps of charge current now but 60 amps in the future.

However, even if you could increase the charge current in the future, you may be restricted by the maximum charge current of your leisure battery and alternator charge current. Always consider the maximum size charger your camper electrical system will allow

Luckily, two DC-DC chargers have current limiting and variable output current features, perfect for future-proofing.

Charger No 1: The Renogy DC to DC battery charger has a ‘current limiting’ feature that lets you reduce the output current by 50%. Therefore, it can run at half current now and then at full current when the battery capacity increases.

For example, The 40A charger can run at 20A (50%).

Further Reading | Discover Renogy’s DC – DC charger current limiting feature

Charger No 2: The Renogy REGO 60A DC to DC battery charger has a variable output current that can be set via the Renogy App. This feature is intended to set the maximum output current for a leisure battery.

The variable current range is 10,20,30,40,50, and 60 amps.

Both chargers are perfect if you plan to increase the battery capacity in the future and will prevent you from needing to upgrade the DC-DC charger, saving precious time and pennies. 

DC-DC + MPPT Solar Charger

Are you planning to install solar panels? Then consider a combined DC-DC charger and solar charge controller. These units are becoming increasingly popular with campervans because they’re more cost-effective, easier to install (one unit instead of 2) and save weight and space. 

Renogy DCC30S DC to DC charger with MPPT Solar

Alternatively, you would need a separate DC to DC charger and a solar charge controller.

However, unlike solar charge controllers, the DC-DC + solar chargers have limited solar panel voltage and power inputs. Overloading the input voltage and power may cause damage to the charger. 

We’ve already discussed how to calculate what size DC-DC charger you need. However, to calculate the solar input of a combined DC-DC + solar unit, you will need to know the open circuit voltage of your solar panel array. 

Follow the steps below or jump to the calculator;

How To

How To – Calculate The Solar Power Input For A DC-DC Charger

Step 1) Open circuit voltage (Voc) of the solar panel.

Each solar panel will have a specification label stating the open circuit voltage; it may be labelled as Voc. We will use Renogy 100 amp solar panels as an example.

For example, the VOC of the 100A Renogy solar panel is 24.3 volts.

Step 2) How many solar panels?

This is the number of solar panels that will be connected together as an array.

For example, 2x Renogy 100A solar panels.

Step 3) How will the solar panels be connected?

Solar arrays are connected in series, parallel or both series-parallel. If you need clarification on what they mean, read about series vs parallel in this post first.

Step 4) How to calculate the total Voc?

Series solar panels = Voc increases (add all solar panel Voc together).

For example, 2x Renogy solar panels in series = 24.3v x2 = 48.6 volts.

Parallel solar panels = Voc remains the same (same value as one solar panel)

For example, 2x Renogy solar panels in parallel = 24.3 volts.

Step 5) Use this Voc value to compare with the DC-DC + solar charger specifications.

Renogy DCC50S maximum solar input voltage

Step 6) The outcome

In our example, the total Voc for the series solar panel array will exceed the ‘Max. Solar Input Voltage’ of the Renogy DCC50S charger. Therefore is NOT compatible.

Total series Voc = 48.6 volts > 25 volts Max of the charger.

However, the total Voc for the parallel solar panel array is less than the ‘Max. Solar Input Voltage’ of the Renogy DCC50S charger. Therefore, IS compatible

Total parallel Voc = 24.3 volts < 25 volts max of the charger.

Calculator #5

Maximum Solar Input Voltage

Series

Solar Panel Voc

No Of Panels

Maximum Solar Voltage

Volts

Parallel

Solar Panel Voc

No Of Panels

Maximum Solar voltage

Volts

DC-DC solar chargers have a maximum solar Voc value. The solar panel total Voc must not exceed the DC-DC charger maximum solar Voc as this will damage the charger.

Renogy 100 watt solar panel electrical data with open circuit voltage highlighted

For Example, the Renogy DCC50S has a maximum Voc of 25 volts. 2x Renogy 100w solar panels wired in parallel have a combined VOC of 24.3 volts. The solar panel Voc is less than the chargers max Voc, so it’s ok. However, 2x Renogy 100w solar panels wired in series have a combined VOC of 48.6 volts. Exceeding the maximum Voc of the charger.

Here’s a comparison table of Voc values for the top 5 DC to DC + MPPT solar chargers:

Typically, solar panels wired in parallel are more suited to DC-DC solar chargers because the open circuit voltage remains low.

If the total solar panel Voc exceeds the maximum values of the charger, consider a separate DC-DC charger and solar charge controller.

Further Reading | The Best DC To DC Chargers With Solar input For Campers

Recap

By determining the maximum size charger your campervan’s electrical system will allow and using the FREE electrical calculators, you should have a clearer idea of how to size a DC to DC charger for your campervan. 

Still unsure what size DC to DC charger you need? No worries! Try our free DC to DC charger electrical calculator – simply fill out the form and let us do the rest. Our expertise and information in this blog post will help us determine what size DC to DC charger is best for your needs. 

Once you know what size DC to DC charger you need. The next step is to find the best DC to DC battery charger for your campervan.

Along with the consideration of buying or leasing an electric vehicle is what type of EV charger you will use at home. As an EV driver, it’s a good idea to factor this plan into the cost of ownership. But first you’ll need to find out about home charging and consider your specific requirements. Where do you park your car? How many miles do you drive each day? Most importantly, how quickly would you like your car to charge up?

Another thing to consider is that the cost and convenience of EV battery charging times vary significantly based on your needs. The charger itself is a crucial part of the equation. The type of electric car battery, how much energy it can hold, and the level of battery depletion all play a role in the optimal time needed for charging. Even the ambient air temperature can impact the battery’s ability to accept a charge efficiently.

There are a variety of “plug-and-play” chargers that are ready for immediate use, while some require you to hardwire the installation. This guide will help you learn about the different types of electric car chargers and what features to look for when deciding on a charging system for your electric vehicle.

Level 1 and Level 2 EV Chargers: What’s the Difference?

The significant difference between Level 1 and Level 2 chargers is the rate of speed at which your EV or PHEV (plug-in hybrid electric vehicle) can charge. Level 2 charges up to eight times faster than Level 1. The other big difference is price. For instance, the Level 1 charger is a cord that comes with most new EVs, while Level 2 home charging stations usually cost an average of $2,000 for purchase and installation. But buyer beware: Installation can cost even more if your home does not meet the electrical requirements.

Another thing to know is that both Level 1 and Level 2 chargers connect to the SAE J1772 charge port equipped on all-electric vehicles except for Tesla models. Tesla, however, provides the adapter necessary for its cars to use this same J1772 charging port.

But before you decide which level is for you, consider the pros and cons of these different types of EV charging systems.

Level 1

These plugs use simple nozzle cords with a 120-volt regular plug.

• Pro: It’s free.
  Level 1 chargers use a cord supplied with most EV purchases.
• Pro: You can plug it into a typical household plug.
  This charging cord plugs directly into any standard outlet in your home. Most people’s garages or carports have these types of plugs readily available. As you’ll see below, Level 2 chargers can be expensive to install.
• Pro: It’s great for PHEVs or low-mileage drivers.
  These chargers work well for people who drive less than 30 miles per day. They also work for plug-in hybrid electric vehicles (PHEVs) that take less charge than a fully electric vehicle, known also as a battery electric vehicle (BEV).
• Con: Level 1 is the slowest charger.
  Level 1 chargers provide a “trickle charge” that charges the car very slowly, sometimes taking 11 to 20 hours for a full charge. It’s essential always to have a Level 1 charging cord with you when driving a EV if you need to charge your car while away from home.

RELATED: How Long Does It Take to Charge an Electric Car

Level 2 

Level 2 chargers operate on 240-volt power and can be installed at home.

• Pro: Faster charging.
  In contrast, a Level 2 charger offers many advantages, including that it charges up to eight times faster than a Level 1 device, completing a full charge in only 3 to 8 hours.
• Con: Level 2 requires a unique electrical setup.
  However, the power it requires comes from a 240-volt plug, such as the one you would use for an electric clothes dryer or other major appliance. You can also hardwire it directly into your electrical system. In most cases, installation requires an electrician to safely wire your garage or carport with this type of power.
• Con: Costs.
  Depending on the physical placement of the unit and the required power, it could cost anywhere between $400 and $4,500. These Level 2 charging units are a separate expense. They range in features and price, anywhere from $500 to $1,500. But even with this wide variety of potential costs, experts say to purchase and install these units costs an average of around $2,000. The bottom line: First, get the advice of an electrician to find out if a Level 2 charging station would be worth the expense of installation in your home. Next, find out if your state, municipality, or electric utility offers any installation discounts, which may help defray some of the costs.

RELATED: How to Plug In an EV: Everything You Need to Know

Level 3 

Level 3 chargers use DC current for fast charging.

• Con: Commercial only — for now.
  DC fast charging offers the fastest option and is convenient for quick charges during EV road trips. However, Level 3 chargers are typically only found commercially, including in public and Tesla’s Supercharger stations.
• Con: Needs too much power from home.
  Due to its high voltage nature and the cost of installing a DC direct fast charger in your home, it’s not typically installed in a private home. Not all EVs offer fast charging, though most newer ones provide the software and combination socket that work with a DC plug.

Other Factors That Will Influence Your Choice

There isn’t a one-size-fits-all option for home EV chargers. Your particular situation will influence the type of setup you can have. Consider these factors when choosing a home charging station.

RELATED: How Much Does It Cost to Charge an Electric Car?

Safety and Protection for Animals and Children

• Electricity can be dangerous when misused or used with substandard equipment. When buying any EV charger, look for models that are UL certified. UL certified indicates that the nonprofit safety organization Underwriters Laboratory independently tested the charger. A product lacking this certification doesn’t mean that it is unsafe. But it does show that the charger did not undergo testing to demonstrate that it is safe for prolonged use.
• Keep children and pets away from charger plugs, connectors, and receptacles as with other electrical devices.

Inside (Garage) vs. Outside Charging

• Mounting a charging station on a garage wall will protect the unit from the elements. The interior location also provides a warmer temperature for better charging during the winter in colder regions. However, not every electric vehicle owner can park and charge their car inside.
• Many EV chargers come rated for outdoor use. Look for those with a higher rating from the National Electrical Manufacturers Association, or NEMA, for more protection from the weather. For example, a NEMA-4 rating unit is better protected from windblown rain and snow than a model with a NEMA-3 rating.
• Most charging stations come with holsters to protect the connector when not attached to the car. Whether it’s attached to the unit or a separate remote holster, using it will protect the plug from being damaged by precipitation and dust.

RELATED: My First Time Charging an EV

Hardwire vs. Plug-in EV Chargers

• EV chargers with greater power will charge the car faster, but those models may need to be installed by a qualified electrician.
• Chargers that deliver more than 40-amps must be hardwired. In other words, the unit connects directly to your power supply. This type of installation method is a more permanent option. If the charging unit has problems and needs replacing, an electrician must uninstall it and hook up the replacement.
• For plug-in Level 2 chargers, an electrician will need to install the electrical receptacle if a conveniently located 240-volt outlet isn’t available. However, this can cost less than hardwiring the unit. Other advantages of plug-in Level 2 chargers:
  • Installation of the outlet can take place before your charger arrives.
  • Replacing a faulty unit or upgrading to a different model is simple.
  • Plug-in units can be removed and brought to another location, such as your second home.

Electric Panel

• One of the first questions a potential electric car owner should answer is whether they control their electricity supply. Permission from the homeowners’ association or landlord may require installing a charging station if you live in a co-op, condo, or apartment.
• Homeowners must determine if their existing electrical panel offers the capacity for a dedicated circuit for the charging station. A qualified electrician will assess your service panel to ensure it can sustain the needed electrical power.
• A circuit that can deliver at least 32-amps is required. Installing a 50-amp circuit will help ensure that the charger can provide 40-amps to your vehicle.
• Note that some jurisdictions may require that charging station installations comply with codes and regulations. Check with local authorities to find out if you need permits before installation.

Cable Length

• Ensure the cable that runs from your charging station to the car is made from rugged materials to provide shock protection and safety while charging in wet conditions.
• When shopping for chargers, pay attention to the cable length and whether the location of the charging station will be inside or outside.
• Locate charge points on your family’s EV. Make sure your cable length can reach the connection. For example, a cable that’s less than 20-feet-long might be inconvenient because it would require you to park in a specific direction to plug into the charger.

Smart EV Chargers

“Smart” EV chargers are more advanced Level 2 products. They have features including Wi-Fi connectivity that enable users to engage a smartphone app for enhanced displays to track activity and schedule charging.

Choosing this type of charger typically adds a few hundred dollars to the cost, but many users find the convenience and additional features worth the price. Users can start or stop charging remotely, check on charging progress, or receive reminders if they haven’t already done so.

A popular feature on some smart chargers lets users enter their electric company information into their profile. The chargers generate reports for users to review statistics that calculate how much it costs to power the car. And by communicating with the utility, some smart chargers will avoid peak times and automatically charge during hours when the provider charges less for energy.

The additional expense of a smart charger isn’t worth it to every electric car driver. And for others, the features aren’t necessary for electric vehicle models. This includes the Nissan Leaf, which uses apps that function similarly to those offered by intelligent chargers.

RELATED: Busting the Myths and Fears of Buying an Electric Car

Wireless EV Chargers Coming Soon

In development at several car companies, wireless EV chargers are something to look forward to for charging electric cars. Hyundai’s luxury brand, Genesis, plans this feature as a factory-installed option on its GV60 electric SUV in 2023. Also touting this technology feature are Tesla, Ford, Volvo, Hyundai, and Kia.

The charging unit will consist of a power receiver on the vehicle, a wall box connected to the electric source, and a charging pad on the ground that connects to the box. A car will park directly over the charging pad to receive between 35 and 40 miles of range per hour of charging at about 11 kilowatts without using a nozzle.

Related Electric Car Guides:

Editor’s Note: This article has been updated for accuracy since it was originally published.

Are you interested in learning more about Public Charging Station? Contact us today to secure an expert consultation!