By Paul Bindon
All photos by MGS Tech
In previous articles, we focused on the types of technology found in vehicles around us. We can now apply what we know in a real-life extrication scenario, see what problems may arise, and illustrate possible solutions that may be used.
Keeping in mind that hybrid vehicles have four tires and a steering wheel just like all the other vehicles on the road today, the major difference is the propulsion system. Take a conventional vehicle, add a traction motor and high-voltage battery, and you basically have a hybrid. This is an oversimplification, but the point is that extrication procedures will differ little for hybrid and conventional vehicles in most cases. Consider the diagram below. Note the position of the high-voltage battery, orange high-voltage wires, and inverter/traction motor. Can you remove the roof of this vehicle for patient access without encountering the high-voltage system?
(1)
Yes, you can. The high-voltage components are not near the pillars supporting the vehicle roof. We can take this a step further and also see that extrication procedures involving door removal, dash displacement, and B-pillar removal are also not affected by the high-voltage components. Since most motor vehicle accidents involve vehicle damage that allows patient access with these methods, procedures will not differ in these cases just because the vehicle is a hybrid. Most hybrid vehicle manufacturers place the high-voltage battery under the rear seat (SUV) or low in the trunk/cargo area. Some sedans, such as the Honda Civic/Accord Hybrid and the Ford Fusion/Mercury Milan/ Lincoln Mark Z Hybrid, have high-voltage components such as the battery behind the seat in a vertical position. This may save cargo space in the trunk by placing these parts up against the back of the passenger seats, but it can also limit access when performing a tunneling operation through the trunk of the vehicle.
All hybrid vehicles have a high-voltage battery disconnect (also known as the “orange plug”) of some kind on the high-voltage battery. The location of this disconnect varies according to vehicle type. Some are easily accessible, like the Ford Escape Hybrid or Toyota Prius, which are in the rear of the vehicle. Others are not as easily found. Several hybrid models, including the Honda Civic Hybrid, place the high-voltage battery disconnect on the front side of the battery, behind the rear passenger seat back. To access the high-voltage battery disconnect on these models, you must remove the rear seats. The original purpose of these disconnects was to isolate the high-voltage electricity within the battery assembly for maintenance purposes. Little thought seems to have been given to first-responder access to these disconnects.
Removing the high-voltage disconnect will disable the hybrid system (propulsion only). You may have thought that pulling the orange plug was a complete power down in the past, but this is only part of the necessary procedure. All systems in the vehicle are controlled by the 12-volt (V) battery, including supplemental restraint systems (SRS) and the High Intensity Discharge (HID) lighting systems, which will require further action before the vehicle is properly powered down.
SRS systems are controlled by computers that run on 12V. Capacitors in the SRS computer will keep the system operational for a period of time after the 12V battery has been disconnected. These capacitors are designed to allow the system to remain operational if the vehicle’s battery is damaged in a collision and the vehicle has not yet come to a stop.
The wiring for the SRS system is not integrated into the circuits for the rest of the vehicle. Air bags have their own “+” and “–“ wires that do not use the body of the vehicle as part of the circuit (ground). The electrical power needed to deploy the air bag is supplied by the SRS computer. This computer is supplied with a constant 12V power source from the battery and a switched power source from the ignition circuit. Each of these two power sources must be available for the computer to be operational and be able to deploy an air bag. Auxiliary power sources, such as cell phones that are connected to the vehicle, are, therefore, unable to power the SRS system and accidentally deploy air bags.
HID System Importance
HID lighting systems also run on a 12V circuit. These systems use a step-up transformer to create an electrical arc within the quartz tube of the headlamp bulb. The operating voltage of this system is approximately 25,000V. This arc heats up the gas within the tube to create a very bright light source. This high-voltage/low-amperage system does not create a lethal amount of voltage; however, the arc is hazardous in that it is an ignition source and can cause an electrical shock. Vehicles that are damaged in a frontal collision have the potential to arc if you come into close contact with that part of the vehicle.
Example Scenario
Now, let’s build a scenario and see how it unfolds.
After your 360° evaluation from a safe distance, you have determined that the Honda is on and running. Neither vehicle is on fire, and you have found the truck has a load of fluffy soft down pillows. No flammable fluid leaks were found. You have the equipment available for proper vehicle stabilization.
(3) Honda Civic Hybrid Trunk View
(4)
(5)
This scenario is set up with enough information to prove a point. The real-life aspect of this scenario coupled with the knowledge previously provided should enable you to realize that previous tactics provided by vehicle manufacturers are not an option. The legal ramifications and perfect scenario perspectives of “official” guidelines and recommendations do not apply to the real-life situations often encountered by firefighting and rescue personnel.
In our next article, we will explore possible solutions to the scenario, including those submitted to the link below.
Send your solution and your source of information to HybridUnderride@mgstech.net
Paul Bindon is a research specialist for MGS Tech and an on-site trainer, and has completed extrication training at the Corona-X seminar. He is also an ASE certified master auto technician with more than 23 years experience in the automotive field. He has been employed with Lexus dealerships for the past 16 years; he has received master diagnostic specialist and hybrid certification through factory training in the latest automotive technologies.