Building EVs the Right Way: A Safety-Centric Guide for Enthusiasts

A Guide for the Aftermarket EV Community

As electric vehicles (EVs) continue to revolutionize the automotive world, a passionate group of enthusiasts is driving another revolution: converting gas-powered vehicles to electric. Whether you’re working on a classic car conversion or building a custom EV from the ground up, safety should be your top priority. High-voltage (HV) systems bring unique risks that must be managed with care. In this article, we’ll explore the essential safety components and protocols to ensure your EV project is both powerful and safe.

High-Voltage Interlock Loop (HVIL)

When you’re dealing with high-voltage systems, the High-Voltage Interlock Loop (HVIL) is your first line of defense. Think of the HVIL as an alarm system for your EV’s electrical components. It’s a continuous loop that runs through all HV connectors and components. If someone accidentally disconnects a plug or if a connection is damaged, the HVIL detects it immediately because there is no longer electrical continuity through the HVIL circuit.

The beauty of HVIL is in its simplicity: it shuts down the high-voltage system to prevent electric shock or fires. This is especially important in DIY builds where safety checks might not be as rigorous as in factory-built vehicles. Integrating an HVIL into your project is critical for ensuring that high-voltage components are only active when everything is safely connected.

This HV heater element harness from a Nissan Leaf has HVIL external to the connector housing.
As seen on this Legacy EV training bench, each HV connection (orange) also has a corresponding HVIL interlock connection (white)

Isolation Monitoring

Isolation monitoring is the unsung hero of EV safety, quietly keeping an eye on the electrical separation between high-voltage and low-voltage systems. In the world of EV conversions, this is particularly crucial. Poor isolation can lead to electrical shocks, short circuits, and damage to your vehicle’s electronics.

Isolation monitors continuously check the insulation quality, aiming for a value above 500 Ohm/V, which is considered the safety standard. This system will alert you if there’s a problem, like a coolant leak causing a short circuit, which might otherwise go unnoticed. Regular isolation monitoring ensures that minor issues are caught early before they can turn into costly or dangerous problems.

A specialized tool, called a megohmmeter can accurately measure the degree of HV isolation during the commissioning and build process.
Some HV connections have HVIL internal to the connecting housing.

High-Voltage Discharge Circuits

If you’re new to EV building, here’s something that might surprise you: even when your EV is off, the high-voltage system can still store enough energy to pose a serious risk. High-voltage discharge circuits are built into EV components such as inverters and designed to safely discharge this stored energy when the vehicle is powered down.

Imagine turning off your EV and getting ready to work on it, only to find out that there’s still high voltage lingering in the cables. Without a discharge circuit, this energy could remain for minutes or even hours, creating a hazard. Discharge circuits can reduce this voltage to safe levels in seconds, protecting you and your vehicle during maintenance.

Once built, products such as the Thunderstruck Motors Ground Fault Monitor can alert the system and user if a loss of isolation is detected.

Covered and Secure High-Voltage Connections

In the aftermarket world, it’s tempting to focus on performance and aesthetics, but safety should always be a priority. Exposed high-voltage connections are not just a safety hazard—they’re a recipe for disaster.

To keep your EV safe, ensure that all high-voltage connections are covered and secured. Use high-quality enclosures like NEMA or IP67 rated housings, which protect against dust, moisture, and accidental contact. Battery boxes should be equipped with fasteners that require multiple steps to open. The rule of thumb here is simple: if you can see or touch a high-voltage connection, it’s not safe. Keeping these connections covered and secure will prevent accidental shorts and protect anyone working on or around the vehicle.

Most inverters, such as this CM200 have active discharge circuits built internal to the device.

 

Proper Component Ratings and Assembly

When building or converting an EV, using the right components isn’t just a matter of performance; it’s a matter of safety. All components, from connectors to resistors, should be rated for the specific demands of your high-voltage system. This is especially critical in conversions where parts might not always match perfectly.

Choose components that meet or exceed the operational requirements of your EV. Always check voltage, temperature, and flammability ratings. And don’t overlook the small stuff—using the correct crimping tools for high-voltage connectors can prevent shorts and isolation faults. Proper assembly is just as important as selecting the right parts; sloppy work can lead to serious safety issues down the line.

Thermal Management

Thermal management is about more than just keeping your EV running smoothly—it’s a crucial part of safety. Batteries and other high-voltage components need to stay within certain temperature ranges to avoid overheating, which can lead to reduced battery life, decreased performance, or even thermal runaway (where temperatures spiral out of control).

For conversions, consider how you’ll manage heat. Passive cooling with heat sinks and fans might work for lower-power builds, but more robust systems benefit from liquid cooling setups, which offer more consistent temperature control. Advanced systems might include an AC chiller for precision cooling under heavy loads or in hot climates. Keeping your components cool not only enhances performance but also ensures safety and longevity.

Understanding component specifications and ratings is an essential part of building a safe EV.

Safety Indicators and Disconnects

Don’t underestimate the importance of having clear safety indicators and quick-disconnect options in your EV build. High-voltage status indicators, like LEDs, provide real-time feedback about the vehicle’s electrical state. In motorsports, these indicators are critical, but they’re just as valuable for everyday EV use. A blinking red LED can alert you that high voltage is present, while a green LED indicates the system is safe.

Emergency disconnects, such as kill switches or E-stop buttons, are essential for safety. These switches allow you to cut power immediately in case of an emergency, protecting both the vehicle and anyone working on it. Make sure these are easily accessible and clearly marked.

Additionally EVs should also have a way to isolate the battery pack from the rest of the system in maintenance or emergency situations, such as Manual Safety Disconnect (MSD) or High- Voltage Battery Disconnect (HVBD).

Long-Term Storage

Planning to store your EV for a while? Long-term storage requires a few specific steps to maintain the health of your high-voltage battery and overall vehicle safety. Start by disconnecting the 12V battery to prevent it from draining over time. If your EV has a high-voltage disconnect, use it to isolate the battery pack.

Maintaining the right state of charge (SOC) is also critical. Store your EV with an SOC between 30% and 80%. This range helps protect the battery from over-discharge or overcharging, both of which can reduce its lifespan. Finally, store your vehicle in a climate-controlled environment—extreme temperatures and high humidity can damage the battery and other components.

Conclusion

Building or converting electric vehicles in the aftermarket space is an exciting endeavor that offers endless opportunities for creativity and innovation. However, with great power comes great responsibility. Adhering to safety best practices—like integrating HVIL, using proper isolation monitoring, ensuring secure high-voltage connections, and managing thermal conditions—will help you build EVs that are not only high-performing but also safe and reliable. By focusing on safety, you can enjoy your EV project with peace of mind, knowing that you’ve created a vehicle that’s as safe as it is thrilling to drive.

Two radiators, one for battery cooling and one for motor cooling, are necessary to keep this converted EV operating at peak power and safety.


This Delorean, converted via the Ampere EV Atom Drive System, has indication available via the touch screen interface, and an e-stop is seamlessly integrated into the PRND controls.
This truck, built to race in the 24 Hours of Lemons, has an obvious e-stop button which is essential in motorsport applications.

 

 

 

 

 

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